DE8429277U1 - Multi-layer chimney - Google Patents

Description

- 2
Zurich Brickworks, Zurich.

HehrschaLiger chimney

The invention relates to a multi-layer chimney according to the preamble of claim 1.

Multi-layer chimneys of the type mentioned above are known, for example from DE-OS 32 11 536. In the examples shown there, the flow channels are either evenly distributed over the circumference or concentrated in the corner areas in order to achieve more favorable flow conditions for the ventilation gas. If the corner areas are completely open, the support of the thermal insulation layer is insufficient. In addition, reinforcing iron can no longer be accommodated in the corner areas. In order to improve the support of the thermal insulation layer, examples are also described in which the flow channels are arranged in the casing in the corner areas and are connected to the thermal insulation layer via connecting channels. With such a design, the support of the thermal insulation layer is improved, but there is no longer enough space in the casing to provide a recess for the reinforcement iron. In addition, the ventilation of the thermal insulation layer is insufficient.

The object of the invention is to improve a chimney of the type mentioned at the beginning in such a way that, on the one hand, optimal flow conditions for the flow channels are achieved, while on the other hand, good support of the heat

% insulation layer And finally the possibility of accommodating

¹ ' reinforcing iron is given.

■ 11 Ii I I I < I I

ti* ItIII* I

t ·' f I III II

< « I » · i I III II

* I»* ! 111! Il I I I 1 I

'" * t 1 ( i i

This problem is solved by the characterizing features of claim 1. Because the flow channels are concentrated on both sides of the corner areas, a wall section remains in the corner area on the one hand, which ensures that the thermal insulation layer is supported, and on the other hand, the casing in the corner areas contains enough material that recesses can be provided that run parallel to the axis of the chimney and can be used to accommodate reinforcing iron. This results in a chimney that offers optimal conditions in terms of the flow properties of its flow channels and strength properties.

Advantageous embodiments of the chimney are described in claims 2 to 4.

A design according to claim 2 is particularly advantageous, since the strength properties of the casing and the cross-sections of the flow channels are optimally coordinated with one another.

It is also advantageous, according to claim 3, to round off the transitions of the casing at the flow channels to the thermal insulation layer, since this avoids damage to the thermal insulation layer* which could be caused by sharp edges.

The design according to claim 4 is particularly useful, since the recesses used to accommodate reinforcing iron and/or casting compound have sufficient space in the corner areas of the casing and also provide the best strength values there.

The chimney can be built up and assembled from individual elements. It is also possible to build the chimney from prefabricated elements in which the inner pipe, the thermal insulation layer and the casing are assembled into a single unit, which then simply need to be placed on top of each other to form a chimney on site.

An exemplary embodiment of the chimney according to the invention is described in more detail below with reference to the drawings, in which:

Figure 1 shows a chimney in cross section and

Figure 2 shows the chimney of Figure 1 in longitudinal

section II-II of Figure 1.

The chimney shown in the figures has a round inner pipe 2, which is made of fireclay, for example. This inner pipe is surrounded by a thermal insulation layer 4, which contains, for example, mineral fibers including glass fibers as the base material. The outer part of the chimney is formed by the casing 6, which is designed as a casing brick and can be made of any material such as clay, concrete, in particular fiberglass concrete, sand-lime brick and the like. In the present example, the casing brick has a square cross-section, but the cross-section can also be pentagonal or polygonal. The casing is provided in the corner area 8 with a recess 12 running parallel to the axis 10 of the chimney, in which a reinforcing iron 14 is arranged. The recess 12 is also filled with a casting compound 16, e.g. a lime-cement mortar. The corner area 8 extends by means of a wall part 18 of width b up to the thermal insulation layer 4.

III! ( , &ldquor; »<««

Flow channels 20 are arranged on both sides of the corner areas 8, which run from bottom to top parallel to the axis 10 of the chimney. The flow channels 20 have an approximately triangular cross-section. The transitions 22, 24 of the casing 6 on the flow channels 20 to the thermal insulation layer 4 are rounded. The wall parts 26 of the casing 6 which delimit the flow channels 20 on the outside have a thickness d which is equal to the width b of the wall part 18 which is adjacent to the casing 6 in the corner area 8.

As can be seen from Figure 2, the chimney is constructed in sections from various elements of the casing 6, the thermal insulation layer 4 and the inner pipe 2. There are mortar joints between the individual elements (not shown in detail). The flow channels 20 are connected at the lower end to an inflow channel 28, which can be arranged, for example, around a smoke pipe connection 30. At the upper end of the chimney, the ventilation gas exits to the outside via an exhaust air channel 32.

The present chimney is characterized by optimal strength properties, which are provided by a uniform jacket thickness in the corner areas 8 and the reinforcing iron. Despite the large attack surface of the flow channels 20 on the thermal insulation layer 4, there is still uniform support of the thermal insulation layer 4* on the jacket 6.

ti ··<» ta ti

&bull; !111 ·· \ ',.'

I ' · tt · t ,

till. ·>··· ,.

&mdash; 6 ~

Reference list

b Width of

d thickness of 26

2 inner tube

A thermal insulation layer

6 Sheathing

8 Corner area

10 Axis

12 Recess

14 reinforcing iron

16 Casting compound

18 Wall section

20 Flow channel

22 Transition

24 Transition

26 WandtenL

28 Inflow channel

30 Smoke pipe connection

32 Exhaust duct

Claims (4)

. Multi-layer chimney with at least one round inner pipe carrying flue gas, a thermal insulation layer surrounding the inner pipe and a casing supporting the inner pipe on the outside with a polygonal outer cross-section, with flow channels running from bottom to top and concentrated in certain areas cooperating with the outside of the thermal insulation layer, characterized in that the flow channels (20) are concentrated on both sides of the corner areas (8). 2. Chimney according to claim 1, characterized in that the width Cb) of the wall part (18) of the casing (6) adjacent to the heat-insulating wall (4) in the corner region (8) corresponds approximately to the thickness (d) of the wall parts (26) of the casing (6) delimiting the flow channels (20) to the outside. 3. Chimney according to claim 1, characterized in that the transitions (22, 24) of the casing (6) at the flow channels (20) to the thermal insulation layer (4) are rounded. 4. Chimney according to claim 1, characterized in that the casing (6) in the corner regions (8) has recesses (12) running parallel to the axis (10) of the chimney, preferably closed on the circumference, for receiving reinforcing iron (14) and/or casting compound (16). 3Ö.Ö8.1984 Chimney, rear ventilated &diams; * * * * Il Il With···· &bull; * · · t * IIII 4 t · · * tii t &igr; i &bull; ti*·* t 1(1 II ■ ■ · · · Il I ■