DE4418872A1 - Quadratic shaft element esp. for chimneys - Google Patents

Abstract

The element has an outer shell (6) with an outer contour with channels running parallel to th axis of the central axis of the element. The inner shell of the element has a contour which, in the corner region approaches the outer shell. Both inner and outer shells are joined to one another to form a single unit through a cellular structure which has a series of channels. The cross-section of the corner channels is larger than the other channels. The inner shell has an octagonal cross-section but the outer shell is of quadratic cross-section.

Description

The invention relates to a cuboid shaft component, especially for the construction of management shafts or chimneys comprising an outer shell with substantially rectangular, four outer outline pages and one to the outer shell axially parallel, a useful channel closing inner shell, the inner contour of which is in its d. H. the corners of the outer contour of the outer shell Ver inner contour areas inclined to the outer contour sides runs, the inner shell and the outer shell by a Cell structure are integrally connected and where the cell structure is formed by cell walls run axially parallel to the inner shell and the outer shell the cell channels.

Such a shaft component is from DE 40 24 823 A1 known. In this known embodiment, the user channel a circular cross section. The cell channels are in one A plurality of circular concentric to the useful channel Wreaths arranged between the service channel and the outer outline. This results in a very large number of cell channels. All these cell channels are unsuitable for the absorption of hardened building materials such as cement mortar, which can also be Introducing have a relatively viscous consistency and therefore not or only with a very large amount of work can be filled reliably. In the corner areas of the The cell channels are arranged in the outer segments of the crown. The cross sections of the cell segments are also very narrow here. If the known segments, as proposed in DE 40 24 823 A1 are to be made of clay using hole technology, so is a very large and for the production of extruder nozzles expensive manufacturing effort offered. It is also through the large variety of cross-sectional small cell channels with one large amount of energy required for extrusion.

The invention has for its object a shaft component the type designated in a lightweight design with ver reduced effort in the manufacture of the extruder nozzles and with  to produce less energy.

To solve this problem, the invention proposes that a wreath of Cell channels with an approximately rectangular outer envelope outline approximately parallel to the outer contour sides of the outer shell outer envelope outline pages and one to the inner outline of the inside shell with a substantially constant distance has inner envelope outline, the cross-sections of the near-corner Cell channels, d. H. the corners of the outer outline of the outer cell channels close to the shell are larger than the cross sections of the remaining cell channels of the wreath, especially in such a way that the clear cross-sectional dimensions of the cell channels close to the corner Wreath along the outer envelope outline sides approx. 20% to approx. 30%, preferably about 22% to about 26% of the length of the ent protruding outer envelope outline pages.

The design according to the invention results at least in the corner areas of cell channels of large cross-section. This means tet that here relatively simple structures for the Made from extruder dies or other molding tools arise. In addition, when extruding or other shapes Shaping work saved and thus the energy expenditure reduced.

A particular advantage of the large transverse cell channels close to the corner sectional lies in the fact that these with hardening building materials can be filled, so that both the mechanical Stability as well as fire resistance can be increased. It is thanks to the large cross-section of the cell near the corner channels also possible in these reinforcements and in particular Reinforcing iron to accommodate and that through a relatively thick layer of hardened building material on all sides are protected against corrosion.

The possibility of adding hardening building material into the corner cell channels, possibly in connection with  Reinforcing bars is of particular importance for the shear and rigid connection of successive shaft components ment. You can achieve this by being in each other aligned cell channels of successive shaft components reinforcing bars bridging the joints and hardening Bring building material mass.

The inner contour of the inner shell can be in octagon shape with two Pairs from each other, facing each other, to the outside outline sides of the outer shell approximately parallel inner outline main pages and with four each at approx. 45 ° to the Interior outline main pages, approximate to each other of equal length, compared to the length of the main inside outline preferably shorter inner contour edges are formed.

This embodiment of the invention leads to the fact that on the whole circumference of the shaft component an approximately evenly ßig mass distribution, what for drying and firing properties of the shaft component is important. If in a pipeline, for example a pipe exhaust pipe in case of chimney construction is to be installed, thanks to the octagonal cross sectional shape of the utility channel is nevertheless approximately the same moderate distance between the pipeline and the inside outline of the Guaranteed useful channel. On the other hand, folding the Interior outline, the cell channels close to the corner with the largest possible Cross section.

It has been shown that the cells structure on a single wreath of Cell channels can be restricted. This is again from great advantage in terms of manufacturing relatively fancy extruder nozzles or other shapes and is also in front partial with regard to, especially when extruding, deformation energy to be used.

It is possible that the outer contour of the outer shell is approximate  is square that the outer shell and the inner shell koa are arranged axially that the inner outline main pages and the Inner outline folding sides are each the same length with each other and that the outer envelope outline is square and concentric the outer outline of the outer shell.

In addition, it is also possible that the outer contour of the outer shell has shorter and longer rectangular sides that the inside main outline sides and the inner outline folding sides with each other are each the same length and that outside the wreath of Cell channels along at least one of the short sides of the rectangle of the outer contour at least a number of further cell channels len is provided.

The application of one or the other embodiment rich depends on the respective building and on the Er Direction of the building available and desired building block information mate.

It is in both of the above-described exemplary embodiments partial if the cell channels close to the corner of the wreath have a five angular outline with four arranged in pairs in a rectangular shape pentagonal sides of equal length and one close to the useful channel have the fifth pentagon side, which is then approximately parallel runs to the respective inner contour folding side. This cross sectional shape has proven to be particularly beneficial in this regard proved that reinforcement bars with approximately uniform Distance from the inner contour of the cell channel close to the corner can be relocated and therefore all around from an equally thick, corrosion-resistant layer made of harden surrounded building material mass.

Between two successive, i.e. H. neighboring corner Cell channels of the wreath can be essentially rectangular Cell channels can be arranged in series. It is sufficient in the Usually, between two or three consecutive corners To provide only two further cell channels for cell channels,  which in turn can be approximately rectangular in cross section and in particular elongated in the connection direction between the two consecutive cell channels close to the corner.

The cell walls between successive cell channels and the Inner shell can be made with approximately the same wall thickness become. The wall thickness of the outer shell is preferably somewhat more powerful, for example 20 to 30% stronger.

In addition to the possibility already mentioned, the shaft construction element by extruding clay and then firing to manufacture, it is also possible to use shaft components Pour an initially liquid, but then hardened building material to prepare mass in appropriate forms. Here is in particular especially thought of concrete mortar.

Basically, it is possible to construct shaft components according to the invention elements at a low height of, for example, 20 to 30 cm put. In this case you need between two floors different levels depending on the floor height Manhole components. But it is also conceivable that the height of a shaft construction element approximately the floor height of a building works corresponds. Such high shaft components can especially in extruder technology.

It was pointed out earlier that the corner Cell channels for filling with hardening building material and if necessary for the introduction of reinforcement material are suitable. If this filling of the cell channels close to the corner especially with regard to the shear and bending resistant Ver binding of successive shaft components is provided, the possibility should also be covered that in individual shaft construction elements individual or all and in particular the corner cell channels with a stability-enhancing or / and filled with a refractory filling compound are. The filling compound can also be introduced in liquid form here then be hardened. The introduction of the filling compound into the  Cell channels and in particular in the cell channels close to the corner can be in the factory in which the shaft components, for. B. be made from brick clay. But it is also conceivable to Weight reduction when transporting the individual shaft Filling components individually at the construction site.

The shaft component is often integrated into buildings builds, so that special measures to shear and bending resistant increasing connection can be avoided. But it is conceivable that individual shaft components with connection means for connection with subsequent similar ones Shaft components are executed.

The connecting means can, for example, screw connections be medium. According to a preferred embodiment is before seen that the connecting means of at least one End surface protruding freely, received in cell channels and there reinforcement bars fixed by hardened building material mass are formed, which are in the free spaces of corresponding cell channels adjacent shaft components can be inserted. Prefers one sees that the reinforcement bars in particular Due to handling on construction only over one end face of the Survive shaft components. Around one and the same shaft Building element in a two-way assembly of shaft building elements ver as both the upper and lower shaft components To be able to turn, it is provided that the respective shaft component in a partially with hardened building material filled cell channel a free of building material mass, Free space near the end face to accommodate a protruding one Reinforcing bar end section of a subsequent manhole structure has.

To then push and push the successive shaft components to be rigidly connected to each other, you can again operate hardening building material mass, which in this case high quality and particularly high adhesion to the security elements should have. Subsequent to this freedom  To be able to fill with building material, you can ensure that the clearance with one of the outer peripheral surface of the Shaft component from an accessible filling opening for the Filling of the hardening building material mass into the free space leads is. This filling opening can be made so large be that it becomes possible even before the construction is introduced mass of material in the free space within the free space itself overlapping reinforcement bars of the one above the other Manhole components by gluing or welding or wiring connect with each other.

It has already been pointed out above that ins especially in the construction of chimneys to accommodate a flue gas pipe is thought within the shaft construction. Although one Such flue gas pipes are preferred at the construction site as required the progress of the height and in particular the height of the height steps of the shaft construction begins, it is nevertheless possible that even individual shaft components with Flue gas pipe sections are pre-assembled.

In particular with chimney structures, it is desirable that the Pipe section with its outer circumference in all directions Distance and as even a distance as possible from the inside circumferential surface of the utility channel is held.

The pipe section can by spacers on the Shaft component to be fixed.

It had been pointed out above that the shaft can also produce components at storey height. Since the Ge lap heights are often variable, it turns out in particular in large industrial production as difficult, for everyone to storey heights correspondingly long shaft components manufacture and keep in stock. It is therefore also the Possibility of a shaft component column considered, which consist of a plurality of arranged in alignment with each other and interconnected shaft components of the above  described type may exist. The connection between the successive shaft construction elements of such a column basically only needs to act so far that the respective pillars transported from the factory to the construction site and can be moved there. There can then be in any Way the final connection will be made.

In the manufacture of prefabricated pillar components can their individual shaft components already factory or connected to each other at the storage location of a construction company be that aligned cell channels, in particular corner cell channels of successive shaft components with hardening building material mass, if necessary, under simultaneous use of reinforcements, such as rebar.

Even in the case of those composed of several shaft components set columns can Ver binding agent for connection with subsequent shaft components elements or shaft component columns can be provided.

However, it is also possible to have it factory-made on site Manufactured floor-to-ceiling column components with low To combine shaft construction elements and thus the desired height to reach. Warehousing for storey-high shaft components This significantly simplifies the pillars of the ment.

If one uses the column principle described above, on the one hand, there is the possibility of installing something Pipe sections into the columns only at the construction site use; on the other hand, there is also the possibility that these shaft component columns are already in the factory or at the construction site before being brought into the growing structure combined with a pipe section of appropriate length become.

The pipe sections can also be used in the shaft construction element columns by spacers at a distance from the inside  circumferential surface of the utility channel can be fixed.

In the case of storey-high shaft component columns, the uppermost Spacers up to 50 cm from the top edge of the column be set low. This can cause the shaft column to move the installed pipeline down from the shaft be drawn. This facilitates the fitting together individual pieces of pipeline considerably. When putting on the The pipe element then pushes the pipe in the shaft up and is back with the top edge of the manhole column flush.

The shaft components according to the invention and the approximately Column elements formed come in buildings of any size and design for use, in particular for the erection of Exhaust chimneys of the respective fireplaces but also for exhaust air derivation, for example from underground garages. For such structures there are fire protection ordinances that usually prescribe ben how long a particular building structure, e.g. B. a wall, predetermined fire or fire conditions on the one hand must withstand the wall without a breakthrough after the other side of the wall is to be expected. A fireplace is in the back view of fire or fire protection a particularly sensitive part of a building because of a fireplace in a variety of rooms often adjacent to several floors and partly also Be part of the partition walls between individual rooms Floor is. It has been shown that the fiction Chimney constructions manufactured according to shaft construction elements suitable for compliance with strict fire protection regulations are, although the between the useful channel and the outside of the Outer shell existing wall thicknesses relatively small are. This beneficial behavior is attributed to that the fire protection properties are not just through the wall thickness between the service channel and the outer circumferential surface is determined, but through the overall stability of the shaft construction element, which is due to the circular arrangement of the cell structure around the Useful channel is increased around.  

Fire resistance can be achieved by backfilling at least the corner cell channels with hardening building material mass still essential Lich increased.

The shaft components according to the invention are particularly suitable those for the erection of chimney constructions, the one-sided or double sided with a wall inside a building as Part of this wall is to be executed.

The invention further relates to a method of manufacture a shaft construction in the form of a shaft construction elements column or in the form of an integrated part of a building using shaft construction elements or shaft construction elements tens columns, as described above. Here is proceeded in such a way that if necessary in accordance with of building progress in shaft construction elements and shaft construction element columns stacked on top of one another and ver be tied, with the pipeline as construction progresses or after the shaft structure has been completed can.

This process is preferably carried out in such a way that the successive shaft construction elements with mortar be bricked. In addition, to increase the connection strength speed and / or fire resistance with the aligned cells hardening building material. To stiffen the Manhole pillar can also, before backfilling with building material reinforcement, such as reinforcement iron are introduced.

According to the state of the art, it is known during construction of chimney structures made of shaft components and an inner one Flue gas pipeline, the flue gas pipeline or parts thereof to be provided with spacer sleeves and then in the To bring in the shaft. This procedure requires the division work in 2 trades. Since the insertion of the pipes in the finished shaft must also be done from the roof, requires  Occupational safety is a huge effort. In addition, the Type of processing also has significant sources of error as it easy to damage when lowering the line into the shaft the pipe connections, for example when the Ab the mortar joints of the shaft.

In contrast, the invention proposes that in particular the use of the shaft proposed above components according to the construction of the chimney structure Position a manhole component or a manhole construction element column at the top of this shaft component or this shaft component column spacer attached the. It is not absolutely necessary to do this after every one individual shaft component to introduce such spacers; it is rather also conceivable that one only after the opening putting together several shaft components again a position of Spacer elements installed. In the built-in distance The pipe sections can then be inserted into holder elements be pushed, whereby they are automatically fixed.

According to a further aspect, the invention relates to a Spacers suitable for use in the erection of Shaft constructions and in particular chimneys, in which one Pipeline inside a utility duct of the shaft construction laid and at a distance from the inner circumferential wall of the utility duct to be held. The spacer includes a position nierteil, which to fix on a shaft component is formed and also an investment part for investment in the respective pipe section. The part of the system be resilient to when inserting the pipeline or To be able to avoid pipeline section as required. Before the plant part is closed with a pointing surface for the one lead the pipeline or the pipeline section see.

The positioning part is preferably with a height positioning surface designed to rest on the upper end surface of the  each shaft component is determined and on Bring the next shaft component between each the two facing end faces is clamped. In addition, the positioning part is preferably guided with at least a side positioning surface, so that the positioning compared to the service channel cross section with a handle can. The positioning part can be fork-shaped be around one or more wall elements of the shaft structure to embrace. In this way, the spacer can be pre-fixed and does not need to be held by hand when the next shaft component is put on or one required between the two shaft components Mortar layer is applied.

The accompanying figures explain the invention with reference to Embodiments. They represent:

Figure 1 shows a structure with floors and a chimney construction.

Fig. 2 is a cross section along line II-II through a shaft of the discharge structure 1 component according to Fig.

Fig. 3 is a section along line III-III of Figure 2 for Dar position of a spacer.

Fig. 4 is a section along line II-II of Figure 1 in a modified embodiment of the invention.

Fig. 5 is a section along line VV of Figure 4 for the presen- tation of another embodiment of a spacer age.

Fig. 6 is a section along line VI-VI of Figure 4 for Dar position yet another spacer.

Fig. 7 shows a further embodiment of a device according to the invention in the shaft wall composite of a building;

FIG. 8 the shaft construction element according to FIG. 7 in a differently constructed wall composite;

Fig. 9 shows a further embodiment of a shaft component according to the invention again on the line II-II of Fig. 1 and

Fig. 10 shows the process of connecting two successive follow the shaft components.

In Fig. 1 you can see two floors of a building, which are designated 1 and 2 . Between the two floor ceilings 1 and 2 and further up and down extends a shaft structure, which is designated 3 in total. A single shaft component is designated 4 . This shaft component 4 is shown in cross section along line II-II of FIG. 1 in FIG. 2.

The shaft component 4 is made of clay in a honeycomb structure and was obtained by extruding clay mass through a multiple extruder nozzle and then drying and firing. The shaft component comprises an inner shell 5 and an outer shell 6 . The outer shell 6 has a rectangular outer contour 6.1 with outer contour sides 6.1.1 , 6.1.2 , 6.1.3 and 6.1.4 . The inner shell 5 has an octagonal inner contour of 5.1 with the Innenumrißhauptseiten 5.1.1, 5.1.2, 5.1.3 and 5.1.4 also belong to the inner contour of the inner umrißabkantseiten 5.1 5.1.5, 5.1.6, 5.1.7 and 5.1.8 .

A ring of cell channels is formed between the outer shell 6 and the inner shell 5 , namely cell channels 7 near the corners and cell channels 8 near the sides. The near-side cell channels 8 have an elongated right-angled cross-section in the circumferential direction of the ring, while the cell channels 7 close to a corner have a five-sided cross-section. The cell channels 7 close to the corner are delimited by cross-sectional sides 7.1 and 7.2 , which are of equal length in pairs, and by a cross-sectional side 7.3 . The individual cell channels 7 and 8 are separated from one another by cell walls 9 . The shaft component 4 is part of a brick wall, which is formed by bricks 10 and layers of plaster or mortar 11 . The outer contour side surfaces 6.1.1 and 6.1.3 are parallel and flush with the masonry.

A useful channel 12 is formed within the inner shell 5 . This useful channel 12 receives a flue gas line 13 . This flue gas line 13 has an approximately uniform distance h from the inner contour 5.1 of the inner shell 5 all around. Spacers 14 serve to center the exhaust pipe 13 within the channel 12 .

An outer envelope outline 15 with envelope outline sides 15.1 to 15.4 is circumscribed to the ring of cell channels 7 , 8 and an inner envelope outline 16 is inscribed. The cross-sectional side length of the cell channel sides 7.1 close to the corner is approximately 20 to approximately 30%, preferably approximately 22 to approximately 26%, of the side length of the outer envelope outline side 15.1 . In order to give a realistic idea of the dimensions of the shaft component, the dimensions a to i have been entered, meaning:
a Inner diameter of the flue gas line 13
b Clear width of the service channel 12
c Brick width 10
d length of brick 10
e Side length of the square outer contour 6.1
f Wall thickness of the inner shell 5
g Wall thickness of the outer shell 6
h Distance of the outer circumference of the flue gas pipe 13 from the inner contour 5.1 of the inner shell 5
i Wall thickness of the cell walls 9 .

In the example, the lengths of dimensions a to i are as follows:
a 90 mm
b 140 mm
c 115 mm
d 240 mm
e 240 mm
f 12 mm
g 15 mm
h 20 mm
i 12 mm.

In Fig. 2 it can also be seen that the corner channels 7 are filled with cement mortar 18 . Reinforcing bars 17 are inserted in the hardened cement mortar 18 , which are surrounded all around by an approximately at least 20 mm thick layer of the hardened cement mortar 18 .

The cement mortar 18 preferably extends over the joints between successive shaft components; this also applies to the reinforcing bars 17 . For technical assembly reasons, however, it is impractical to let the reinforcement bars pass through their entire height in long shaft structures. It is therefore recommended to arrange individual reinforcing bars 17 so that they overlap and run over the joints between successive shaft components.

In Fig. 3 it is shown how the spacers 14 are executed in an individual. These spacers 14 consist of a positioning part 14.1 and a pipe contact part 14.2 , which is centered on the flue gas pipe 13 . The Posi tionierteil 14.1 is carried out with a height positioning plate 14.1.2 and 14.1.3 side positioning legs . The side positioning legs 14.1.3 fork the inner shell 5 preferably in the folded areas 5.1.5-5.1.8 and thus fix the spacer 14 laterally. The height positioning plate 14.1.2 bears against the upper end of the shaft component and is overlaid by the next following shaft component during further construction. The system part 14.2 is made of resilient steel and has a guide surface 14.2.3 , which facilitates the insertion of the flue gas pipe sections 13 .

The construction of the shaft structure 3 according to FIG. 1 generally takes place as the building progresses in height. The Schachtbauele elements 4 are placed one on top of the other with the mediation of a mortar bed. Each time after putting on a new manhole component 4 or after placing some manhole components 4 , the cell channels 7 , which are aligned with one another across all the manhole components, can be filled with cement mortar 18 after the respective reinforcing bar sections 17 have been introduced beforehand. The Rauchgaslei device 13 is constructed in sections. The sections can be divided to the same extent as the shaft components 4 or longer lengths up to 3 m and are inserted in accordance with the progress of the shaft construction in the spacers 14 already installed ver.

The cell channels 8 can also be filled with concrete mortar. As a rule, however, the filling of the cell channels 7 is sufficient. This is simplified because they have the largest cross-section.

The embodiment according to FIG. 4 differs in terms of the cell structure from the embodiment according to FIG. 2 in that three cell channels 108 near the side have been substituted for two cell channels 8 near the side. Another difference is the construction of the spacers. In Fig. 5 can be seen according to the section along line VV of Fig. 4, a spacer in which the side positioning leg 114.1.3 enter the inner shell 105 and the outer shell 106 together, while according to the embodiment of Fig. 6 as a side positioning means only a stop flag 214.1.3 is provided, which is brought to bear on the inside of the inner shell 105 .

According to FIG. 7, the shaft component 304 has different outer contour sides 306.1.2 and 306.1.1 of different lengths . Accordingly, further cell channels 320 are arranged parallel to the outer contour sides 306.1.2 and 306.1.4 . The long outer outline pages 306.1.1 and 306.1.3 are parallel to the longitudinal direction of the wall. The wall is brought to a wall thickness of approx. 360 mm by a layer of bricks 321 in front.

With the same shaft component as shown in FIG. 7, a 300 mm thick wall can also be erected according to FIG. 8. The bricks 410 have a width c of 240 to 365 mm and a thickness d of approx. 300 mm.

In Fig. 9 is a modification of a shaft component Darge provides, in which 505 centering lugs 523 for the flue gas pipe 513 are formed on the inner shell.

In Fig. 10, can be seen as a shaft component 601 a straight b placed on an already built-up shaft component 601 is. It can be seen above the upper end of the shaft component 601 b above the upper ends 617.1 of reinforcing bars 617 . The reinforcing bars 617 of the upper manhole component 601 a also extend beyond the upper end of this manhole component and end at the level of the lower end face. The cell channels 607 near the corner of the upper shaft building element 601 a are only filled down to the level 625 with hardened building material mass or under certain circumstances also filled with light fillers. If the upper manhole component is placed on the top of the lower manhole component 601 b, the upper end sections 617.1 of the reinforcing bars 617 of the lower manhole component 601 b enter the free, lower sections 607.1 of the channels 607 and overlap there with the in these free spaces 607.1 located lower end portions 617.2 of the reinforcing bars 617 of the upper shaft component 601 a. The overlapping end sections 617.1 and 617.2 can then be welded or wired to one another through openings 626 . Then the free spaces 607.1 of the cell channels 607 near the corner can be filled with cement mortar of high quality. In some circumstances, the binding effect that emanates from this backfill is sufficient. The filling of the free spaces 607.1 can take place by means of an auxiliary formwork element 630 , which is brought into overlap with the opening 626 . This auxiliary formwork element 630 is seen with a filling funnel 631 , which is connected via a line 632 to the opening 626 in connection.

If it is found in claim 1 that the cross sections of the cell channels 7 close to the corner are larger than the cross sections of the other cell channels of the ring, this need not necessarily mean that the area of the cross sections of the cell channels 7 close to the corner is greater than the area of the cross sections of the remaining cell channels 8 . An effect in the sense of the invention is already achieved if, regardless of the ratio of the area of the cross sections of the cell channels 7 and 8, the cross sections of the cell channels 7 are selected so that they are easier to fill with a later hardening filler. However, the area of the cross section of a cell channel 7 close to the corner is preferably larger than the area of the cross section of a cell channel 8 .

Claims (40)

1. cuboid shaft component ( 4 ; 304 ; 601 a, 601 b), in particular for the construction of cable ducts or chimneys,
Comprising an outer shell ( 6 ) with an essentially rectangular, four outer outline sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ) and an outer outline ( 6.1 ) parallel to the outer shell ( 6 ) and a useful channel ( 12 ) including inner shell ( 5 ), the inner contour ( 5.1 ) of which is in its near-corner, ie the corners of the outer contour ( 6.1 ) of the outer shell ( 6 ) facing inner contour areas against the outer contour sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ) runs inclined,
wherein the inner shell ( 5 ) and the outer shell ( 6 ) are integrally connected to one another by a cell structure ( 7 , 8 , 9 ) and
the cell structure ( 7 , 8 , 9 ) being formed by cell channels ( 7 , 8 ) bounded by cell walls ( 9 ) and axially parallel to the inner shell ( 5 ) and the outer shell ( 6 ),
characterized,
that a ring of cell channels ( 7 , 8 ) immediately adjacent to the inner shell ( 5 ) has an approximately rectangular outer envelope contour ( 15 ) with the outer shell sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ) of the outer shell ( 6 ) has approximately parallel outer envelope outline sides ( 15.1 , 15.2 , 15.3 , 15.4 ) and an inner envelope outline ( 16 ) which runs at a substantially constant distance from the inner outline ( 5.1 ) of the inner shell ( 5 ), the cross sections of the cell channels ( 7 ), ie the cell channels ( 7 ) near the corners of the outer contour ( 6.1 ) of the outer shell ( 6 ) are larger than the cross sections of the other cell channels ( 8 ) of the ring, in particular in such a way that the clear cross-sectional dimensions of the cell channels near the corner ( 7 ) of the ring along the outer envelope outline sides ( 15.1 , 15.2 , 15.3 , 15.4 ) approx. 20% to approx. 30%, preferably approx. 22% to approx. 26% of the length of the corresponding outer envelope outline sides ( 15.1 , 15.2 , 15.3 , 15.4 ). 2. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 1, characterized in that the inner contour ( 5.1 ) of the inner shell ( 5 ) in octagon shape with two pairs of mutually opposite, to the outer contour sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ) of the outer shell ( 6 ) approximately parallel inner outline main sides ( 5.1.1 , 5.1.2 , 5.1.3 , 5.1.4 ) and with four each at approx. 45 ° with respect to the inner outline main sides ( 5.1.1 , 5.1.2 , 5.1.3 , 5.1.4 ), the inner outline main sides ( 5.1.1 , 5.1.2 , 5.1.3 , 5.1.4 ), which are preferably approximately the same length as each other, but preferably shorter inner outline folding sides ( 5.1.5 , 5.1.6 , 5.1.7 , 5.1.8 ) is formed. 3. shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 1 or 2, characterized in that the cell structure ( 7 , 8 , 9 ) comprises a single, all-round closed ring of cell channels ( 7 , 8 ). 4. Shaft component ( 4 ) according to claim 3, characterized in that the outer contour ( 6.1 ) of the outer shell ( 6 ) is approximately square, that the outer shell ( 6 ) and the inner shell ( 5 ) are arranged coaxially that the inner outline main sides ( 5.1.1-5.1.4 ) and the inner outline folding sides ( 5.1.5-5.1.8 ) are approximately equal in length to each other and that the outer envelope outline ( 15.1 ) is square and concentric with the outer outline ( 6.1 ) of the outer shell ( 6 ). 5. shaft component ( 304 ; 601 a, 601 b) according to claim 3, characterized in that the outer contour of the outer shell has shorter ( 306.1.2, 306.1.4 ) and longer ( 306.1.1, 306.1.3 ) rectangular sides that the The inner outline main sides and the inner outline of the inner shell are each of the same length and that at least one row of further cell channels ( 320 ) is provided outside the ring of cell channels along at least one of the short rectangular sides ( 306.1.2 , 306.1.4 ) of the outer outline. 6. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 5, characterized in that the cell channels ( 7 ) close to the corner of the ring have a five angular outline with four approximately rectangularly arranged, approximately the same length in pairs Have pentagonal sides ( 7.1 , 7.2 ) and a fifth pentagonal side ( 7.3 ) close to the useful channel ( 12 ). 7. shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 6, characterized in that between two adjacent cell channels ( 7 ; 607 ) close to the corner of the ring substantially rectangular cell channels ( 8 ) are arranged in series. 8. shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 7, characterized in that between two adjacent cell channels near the corner ( 7 ; 607 ) of the ring each have two or three further cross-section approximately rectangular cell channels ( 8 , 308 ) are arranged. 9. shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1 to 8, characterized in that the cell walls ( 9 ) between adjacent cell channels ( 7 , 8 ) of the ring and the inner shell ( 5 ) approximately the same wall thickness (i, f). 10. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 9, characterized in that it is produced by extruding a clay mass and then firing this clay mass. 11. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 9, characterized in that it is produced by pouring a liquid but curable building material mass into a mold and then curing. 12. Shaft component ( 4 ; 304 ) according to one of claims 1 to 11, characterized in that its height is small compared to the floor height ( 1-2 ) of a building. 13. Shaft component ( 601 a, 601 b) according to one of claims 1 to 11, characterized in that its height corresponds approximately to the floor height of a building. 14. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 13, characterized in that at least the cell channels ( 7 ) close to the corner of the ring are filled with a stability-increasing and / or a fire-resistant filling compound ( 18 ) . 15, shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 14, characterized in that the filling compound ( 18 ) is brought in a liquid state and is then hardened filling compound. 16. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 15, characterized in that at least part of the cell channels ( 7 ) filled with hardened filling compound ( 18 ) contains reinforcing means ( 17 ), in particular reinforcing bars. 17. Shaft component ( 601 a, 601 b) according to one of claims 1 to 16, characterized in that it is equipped with connecting means ( 617.1 , 617.2 , 607.1 ) for its connection with subsequent, similar shaft components ( 601 a, 601 b). 18. shaft component ( 601 a, 601 b) according to claim 17, characterized in that the connecting means of at least one end surface of the shaft component ( 601 a, 601 b) freely survive the, received in cell channels ( 607 ) and there by hardened building material fixed reinforcing bars ( 617 ) are formed, which can be inserted into free spaces ( 607.1 ) of corresponding cell channels ( 607 ) of adjacent shaft components ( 601 a, 601 b). 19. shaft component ( 601 a, 601 b) according to claim 18, characterized in that it in a partially filled with hardened building material cell channel ( 607 ) a free of building material holding, near the end surface free space ( 607.1 ) for receiving one of an adjacent shaft component ( 601 a, 601 b) in a corresponding cell channel ( 607 ) received and fixed reinforcing bar ( 617 ). 20. Shaft component ( 601 a, 601 b) according to claim 19, characterized in that the free space ( 607.1 ) with an outgoing from the outer peripheral surface of the shaft component ( 601 a) filling opening ( 626 ) for the filling of curable building material mass in the Clearance ( 607.1 ) is executed. 21. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to one of claims 1 to 20, characterized in that it receives a pipe section ( 13 ) pre-fixed in its useful channel ( 12 ). 22. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 21, characterized in that the pipe section ( 13 ) is held at all sides from the inner peripheral surface ( 5.1 ) of the useful channel ( 12 ). 23, shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 22, characterized in that the pipe section ( 13 ) by spacers ( 14 ) on the shaft component ( 4 ; 304 ; 601 a, 601 b) is fixed. 24. Shaft component column ( 3 ) consisting of a plurality of shaft components ( 4 ; 304 ; 601 a, 601 b) arranged in alignment with one another and connected to one another in an at least sufficient manner for transport according to one of claims 1 to 23. 25. shaft component column ( 3 ) according to claim 24, characterized in that it has approximately floor height ( 1-2 ). 26, shaft component column ( 3 ) according to claim 24 or 25, characterized in that it is equipped with connecting means ( 617.1 , 617.2 , 607.1 ) for connection to subsequent shaft components or shaft component columns . 27. Shaft component column ( 3 ) according to one of claims 24 to 26, characterized in that it receives a pipe section ( 13 ) of corresponding length in its useful channel ( 12 ). 28. shaft component column ( 3 ) according to claim 27, characterized in that the pipe section ( 13 ) in the useful channel ( 12 ) by spacers ( 14 ) at a distance from the inner circumferential surface of the useful channel ( 12 ) is held. 29. shaft component column ( 3 ) according to any one of claims 24 to 28, characterized in that the shaft components ( 4 ) of the column are thereby connected to each other that in aligned cell channels ( 7 , 8 ), in particular corner cell channels ( 7 ) one Hardened building material ( 18 ), if necessary in connection with reinforcement means ( 17 ), such as reinforcing bars, is introduced. 30. Building with a shaft structure integrated therein, formed using shaft building elements ( 4 ; 304 ; 601 a, 601 b) or / and shaft building element columns ( 3 ) according to one of claims 1 to 29. 31. Structure according to claim 30, characterized, that the shaft construction at least on one side, preferred instruct two-sided, flush in a wall of the building is ordered. 32. A method for producing a shaft structure in the form of a shaft component column ( 3 ) or an integrated part of a building using Schachtbauelemen th ( 4 ; 304 ; 601 a, 601 b) or shaft component columns ( 3 ) according to any one of claims 1 to 31, thereby characterized in that, if necessary, according to the building site step, the manhole components or manhole elements pillars ( 3 ) are stacked one on top of the other, binds them together and optionally provide at least one pipe. 33. The method according to claim 32, characterized in that for connecting successive manhole elements or manhole pillar columns ( 3 ) aligned cell channels ( 7 , 8 ) or cell channel sections with hardenable construction material ( 18 ), optionally with the introduction of reinforcement elements ( 17 ), like reinforcing bars, in the cell channel ( 7 ) or cell channel section. 34. A method for producing a shaft structure in the form of a shaft component column ( 3 ) or an integrated part of a building, in particular using shaft components ( 4 ; 304 ; 601 a, 601 b) or shaft building element columns ( 3 ) according to one of claims 1 to 31 and with installation of a pipeline ( 13 ), characterized in that after positioning a manhole component ( 4 ; 304 ; 601 a, 601 b) or a manhole component column ( 3 ) at the upper end of this manhole component ( 4 ; 304 ; 601 a, 601 b) or the shaft devices column (3) Abstandhal ter (14) affixes, optionally only after Positionin ren several shaft elements (4; 304; 601 a, 601 b) or shaft components columns (3) and in that thereto Rohrlei processing sections (13) introduces into the useful channel ( 12 ) and fixed by spacers ( 14 ). 35. Method of manufacturing a shaft structure from Shaft components or pillar component columns large Height, especially of floor height, characterized, that in the shaft components or shaft components len pipe sections, especially using of spacers, are used in such a way that them opposite the upper edge of the shaft component or the Shaft component column are set down and accordingly over the lower edge that the each shaft component to be fitted or the shaft component column using the protruding downward  End piece of the respective pipe section opposite the last shaft component installed or the last one built shaft component column is centered and that then the shaft component to be installed or the Shaft component column on the top edge of the last installed shaft component or the last installed The shaft component column is lowered under displacement of the pipe section contained therein upwards. 36. spacer ( 14 ) for use in the construction of shaft structures, in particular using shaft building elements ( 4 ; 304 ; 601 a, 601 b) or shaft building element columns ( 3 ) according to one of claims 1 to 35, characterized in that it has a Positioning part ( 14.1 ), which is designed to be fixed to a shaft component ( 4 ; 304 ; 601 a, 601 b), and further comprises a contact part ( 14.2 ) for contact with a respective pipe section ( 13 ). 37. spacer ( 14 ) according to claim 36, characterized in that the contact part ( 14.2 ) is resilient. 38. Spacer ( 14 ) according to claim 36 or 37, characterized in that the contact part ( 14.2 ) with a guide surface ( 14.2.3 ) is designed for the insertion of the respective pipe section ( 13 ). 39. Spacer ( 14 ) according to any one of claims 36 to 38, characterized in that the positioning part ( 14.1 ) has a height positioning surface ( 14.1.2 ) for resting on the upper end surface of the respective shaft component ( 4 ; 304 ; 601 a, 601 b) and at least one side positioning surface ( 14.1.3 ; 114.1.3 ; 214.1.3 ) for abutment against a wall part ( 5 ; 105 ) of the manhole component. 40. Spacer ( 14 ) according to one of claims 36 to 39, characterized in that the positioning part ( 14.1 ) is fork-shaped for gripping one or more wall parts ( 5 ; 105 ) of the shaft component.