DE4418872C2 - Manhole construction element and manholes or chimney constructions made from it - Google Patents

Description

The invention relates to a by extruding a clay mass and subsequent firing cuboid Shaft component for the construction of shafts or Fireplaces with an inner tube if necessary according to the generic term of claim 1.

Such a shaft component is from FR 2 471 465 known. In this known embodiment, the cell channels assigned to the ring of cell channels in Hexagonal shape, so that it is circumferential direction of the ring a relatively long cross-sectional axis and orthogonally have a relatively short axis, so that they are all elongated in the circumferential direction Have cross-section. The cross section of the hexagonal channels is in relation to the total cross section of the shaft Components kept very small, so that it is hardly possible is these hexagonal cell channels close to the corner of the Inner shell of adjacent ring of cell channels for Housing longitudinal reinforcements and one of these longitudinal reinforcement surrounding hardened filler. In a ring of cell channels adjacent to the outer shell can also be found in this known embodiment near-corner cell channels with pentagonal cross-section, four of the five corner sides arranged approximately in a rectangular shape are and one to an inner contour folding side in the main Chen parallel fifth pentagon side of approximately the same length has like the cross-sectional pages adjoining them. Also these pentagonal cell channels close to the corner have one on the total cross section of the manhole component, very much small clear cross section, so that they too for the Installation of a longitudinal reinforcement and a surrounding one Filling materials are unsuitable.  

From DE-U 19 74 250 a chimney stone is known, at the approximately pentagonal cell channels close to the corner a wreath of cell channels adjacent to the inner shell, based on the total cross section of the cuboid Shaft component, have a relatively large cross section and Pick up steel inserts. If you take these steel inserts with you wants to surround a filling compound, so the steel inserts sometimes relatively close to the limit of the filling mass, see above that optimal corrosion protection of the steel inserts is not is guaranteed. This is based u. a. that the Near, pentagonal cell channels in circumference have a stretched cross-section in the direction of the ring.

The invention is based, with one Shaft component of the type defined at the outset easy installation of reinforcement elements and one of these to enable approximately evenly surrounding filling compound.

To solve this problem, the invention proposes conditions that in the area of inner contour folds located near the corner cell channels of the wreath for receiving Longitudinal reinforcements and a filling compound surrounding them are designed so that they have a pentagonal outline with four arranged approximately in a rectangular shape, in pairs pentagon sides of approximately equal length and one to one Inner contour fold side essentially parallel fifth Pentagon side possess that the clear cross-sectional dimensions solutions of the cell channels of the wreath near the corner along the outer envelope outline sides about 20% to about 30%, preferably about 22% to about 26% of the length of the corresponding outer Envelope outline pages, and that the clear cross sectional dimension of the corner cell channels along the the fifth pentagon side is smaller than the light one Cross-sectional dimension along the respective of the fifth pentagon side distant pentagon sides.  

According to a development of the invention, it is provided that the cross sections of the cell channels close to the corner, which the wreath of neighboring cell channels belong to the inner shell, larger are as the cross sections of the other cell channels of the Wreath to meet the requirements for the installation of Reinforcement elements and one of them almost evenly surrounding filling compound into the cell channels close to the corner to improve.

The design according to the invention brings the additional Advantage that there are relatively simple structures for the extruder nozzles used for molding result.

Due to the - in relation to the scope of the longitudinal reinforcement - Relatively thick layer of hardened building material on all sides improved protection against corrosion is achieved mechanical stability increased and also fire resistant improved.

The possibility of introducing hardening building material mass in the corner cell channels in connection with Reinforcing bars is of special importance for the shear and bending resistant connection of successive Shaft components. You can achieve this by: one follows one another in aligned cell channels the shaft construction elements bridging the joints Reinforcing bars.

The inner contour of the inner shell can be in octagon shape with two Pairs of opposite to each other Outer outline sides of the outer shell approximately parallel Inner outline main pages and with four each at approx. 45 ° opposite to the main inside outline other approximately the same length compared to the length of the Inner outline main pages preferably shorter inner outline bevelled sides are formed.  

This embodiment of the invention leads to the fact that approximately the entire circumference of the shaft component uniform mass distribution, which is important for the drying and burning properties of the shaft component of importance is. If there is a pipe in the octagonal service channel, for example an exhaust gas pipeline in the case of a Chimney construction should be installed, thanks to the octagonal cross-sectional shape of the useful channel approximately uniform distance between the pipeline and the inner contour of the utility channel. Other on the one hand, the fold of the inner outline helps to ensure that cell channels close to the corner with the largest possible cross-section to be able to lead.

It has been shown that when using the invention Cell structure on a single, all around closed Wreath of cell channels can be restricted. This is again of great advantage in terms of manufacture relatively simple extruder nozzles or other shapes and is also advantageous in terms of, especially when Extrude, deformation energy to be used.

It is possible that the outer contour of the outer shell approximates hernd square is that the outer shell and the inside shell are arranged coaxially that the interior outline ten and the inner contour folding sides with each other are of equal length and that the outer envelope outline is square and is concentric with the outer contour of the outer shell.

In addition, it is also possible that the outer outline of the The outer shell has shorter and longer sides of the rectangle, that the inside outline major sides and the inside outline chamfer ten among each other are the same length and that except half of the ring of cell channels along at least one at least one of the short sides of the rectangle A number of further cell channels are provided.  

The application of one or the other embodiment depends on the respective building and on the the construction of the structure available and desired Block formats.

Between two successive, i.e. H. neighboring The cell channels near the corner of the wreath can essentially rectangular cell channels can be arranged in series. Here It is usually sufficient to put one on top of the other the following corner cell channels only two or to provide three more cell channels, which in cross section again can be approximately rectangular and in particular elongated in the direction of connection between the two consecutive corner cell channels.

The cell walls between successive cell channels and the inner shell can have approximately the same wall thickness be carried out. The wall thickness of the outer shell is preferably a little stronger, for example around 20 up to 30% stronger.

Basically, it is possible to manhole according to the invention components at a low height of, for example, 20 to 30 cm. In this case you need between two Floor levels differ depending on the floor height Variety of shaft components. But it is also conceivable that the height of a shaft component is approximately that Floor height of a building corresponds. Such high Shaft components can easily be extruded getting produced.

In addition to the cell channels close to the corner of the inner shell adj beard wreath of cell channels can further cell channels with a stability increasing or / and a fire resistant increasing filling mass can be filled. Here too the filling compound is introduced in liquid form and then hardened become. The introduction of the filling compound into the cell channels and  Especially in the cell channels close to the corner can be in the factory take place in which the shaft components, for. B. from Brick clay can be made. But it is also conceivable to Weight reduction when transporting the individual shaft Filling components individually at the construction site.

It is conceivable that individual shaft components with Connection means for connection with subsequent similar shaft components are executed.

The connecting means can for example screw be binding. According to a preferred embodiment it is provided that the connecting means of at least at least one end surface protruding freely in cell channels absorbed and there by hardened building material mass fixed reinforcing bars are formed, which in Clearances of corresponding cell channels in the adjacent shaft components are insertable. It is preferable to provide that the reinforcing bars, in particular for the sake of Handling on site only over one end of the shaft survive components. Around one and the same shaft Building element in a two-way assembly of shaft building elements both as an upper and a lower shaft construction element To be able to use it is provided that the respective Shaft component in a partially hardened Building material mass filled cell channel one of building material mass free space near the end face for the recording a protruding reinforcing bar end section of a subsequent shaft component.

To then push the successive shaft components and rigidly connected to each other, you can again use the hardening building material mass, which in in this case particularly high quality and particularly high Should have adhesion to the reinforcement elements. To the Completely fill in free space with building material can, you can ensure that the space with a  from the outer peripheral surface of the shaft component accessible filling opening for filling the erhär tendency building material mass is executed in the free space. This The filling opening can be made so large that it becomes possible even before the building material is introduced into the free space that overlap within the free space Reinforcement bars of the stacked shaft components elements by gluing or welding or wiring to connect others.

Especially in the construction of chimneys, the accommodation of a Flue gas pipe inside the shaft construction. Although such flue gas pipes are preferred on the Construction site in accordance with the height progress and in particular the construction progress of the shaft cone structure, it is nevertheless possible that individual shaft components already with flue gas pipe sections are pre-assembled.

In chimney structures, it is desirable that the pipeline section with its outer circumference at all sides and distance as even as possible from the inner circumference area of the utility channel is kept. The pipeline section can be by spacers on the shaft component be fixed.

The invention further relates to a shaft or chimney cone fabricated using a plurality of shaft components described above with a Bumps between at least two consecutive Longitudinal arrangement of shaft components reinforcements and hardened filling compound at least in the cell channels close to the corner. Because the floor heights are often variable are, it turns out to be in large industrial factories difficult, for all storey heights correspondingly long shaft components to manufacture and on To keep stock. The connection between the one another  shaft components of such a column basically only to the extent that the respective columns 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 manhole components len can already their individual shaft components factory or at a construction company's warehouse be connected to each other that aligned Cell channels, in particular cell channels close to one another the following shaft construction elements with hardening building material mass are filled with the simultaneous use of Reinforcements, such as rebar.

Even in the case of those consisting of several shaft components Compound columns can be attached to the respective columns connecting means for connection with subsequent Shaft components or pillar component columns be seen.

But it is also possible to factory-made on the construction site prefabricated floor-to-ceiling column components with to combine low shaft construction elements and so the to reach the desired height. Store for storey high pillar components becomes essential simplified.

Using the columns described above principle, on the one hand there is again the possibility about pipe sections to be installed only at the Insert construction site in the pillars; on the other hand but also the possibility that these shaft components already in the factory or at the construction site in front of the Introducing into the growing structure with a pipeline section of appropriate length can be combined.  

The pipe sections can also in the Shaft component pillars with spacers at a distance be fixed by the inner circumferential surface of the service channel.

In the case of storey-high shaft component columns, the top spacer opposite the top edge of the column be set up to 50 cm lower. This allows the Relocate the shaft column to the installed pipeline be pulled out of the shaft at the bottom. This facilitates ters the fitting of individual pipes pieces considerably. When placing the manhole element the pipe then pushes upwards in the shaft and is again flush with the top edge of the shaft column.

The shaft components according to the invention and those derived therefrom Column elements that are formed come arbitrarily in buildings ger size and type of application, especially for Construction of flue gas chimneys for the respective fireplaces but also for extracting air, for example from deep cooking Fire protection regulations exist for such structures, which usually dictate how long a particular one Building construction, e.g. B. a wall, predetermined fire or Withstand fire conditions on one side of the wall must without a breakthrough to the other side of the Wall is to be expected. A fireplace is in view of fire or fire protection a particularly sensitive part of a Building because of a fireplace in a variety of rooms in often adjacent to several floors and sometimes also Part of the partition between individual rooms one floor. It has been shown that the out shaft components according to the invention produced Chimney constructions to meet even severe fires protective regulations are suitable, although the between the Usable channel and the outside of the outer shell existing Wall thicknesses are relatively small. This advantage Adherent behavior is attributed to the fire protective properties not only due to 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 the useful channel is increased around.

The fire resistance is at least due to the backfilling of the cell channels close to the corner with hardening building material mass significantly increased.

The shaft components according to the invention are suitable especially for the construction of chimney constructions one-sided or two-sided flush with a wall inside of a building as part of this wall should.

When building a chimney structure from the invention Shaft components can be positioned according to each a shaft component or a shaft component column at the top of this shaft component or this Install the spacer shaft component column. It is it is not absolutely necessary after every single manhole to introduce such spacers; it is rather, it is also conceivable that only after the Placing several shaft components on top of one another Position of spacer elements installed. In that way built spacer elements can then the pipeline sections are inserted, making them automatic are fixed.

A spacer comprises a positioning part, which trained to attach to a shaft component is det and also an investment part for investment in the respective pipe section. The part of the system be resilient so that when you insert the pipeline or of the pipeline section to avoid as needed can. The plant part with a guide is preferred Area for the insertion of the pipeline or the Rohrlei  provided section. The positioning part can be carried out with a height positioning surface for Support on the upper end surface of the respective shaft component is determined and in the application of next next shaft component then between the is clamped both facing end faces. You can also use at least one of the positioning parts Execute the side positioning surface so that the position tion of the service channel cross-section with one hand can be done. The positioning part can be fork-shaped be formed around one or more wall elements of the shaft construction element. That way the spacer can be pre-fixed and does not need of Hand to be held when the next manhole component is placed or one between the two shaft required mortar layer is applied.

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

Figure 1 is a building with floor ceilings and a chimney construction made of shaft components according to the invention.

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

Fig. 3 is a section along line III-III of Figure 2 showing a spacer.

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

Fig. 5 is a section along line VV of Figure 4 with a modified spacer.

Fig. 6 is a section along line VI-VI of Figure 4 with a further modified spacer.

Fig. 7 shows another embodiment of a shaft component in the composite wall of a building according to the Invention;

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 according to line II-II of Fig. 1 and

Fig. 10 the connection of two successive inventions to the invention 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 5.1 with the inner contour main sides 5.1.1 , 5.1.2 , 5.1.3 and 5.1.4 ; the inner outline 5.1 also includes the inner outline folding sides 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 , specifically one can see cell channels 7 near the corner and cell channels 8 near the side. The near-side cell channels 8 have an elongated right angular cross-section in the circumferential direction of the ring, while the cell channels 7 close to the corner have a five-cornered 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 short 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 construction element, 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 any case 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 lies 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 into 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.

Claims (19)

1. By extruding a clay mass and then firing cuboid shaft component ( 4 ; 304 ; 601 a, 601 b) for the construction of shafts or chimneys, optionally with an inner tube ( 13 ), comprising an outer shell ( 6 ) with a substantially rectangular, four outer sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ) having an outer contour ( 6.1 ) and an inner shell ( 5 ) which is axially parallel to the outer shell ( 6 ) and includes a useful channel ( 12 ), the inner contour ( 5.1 ) of which is in its near the corner, ie the corners of the outer contour ( 6.1 ) of the outer shell ( 6 ) facing inner contour areas inclined towards the outer contour sides ( 6.1.1 , 6.1.2 , 6.1.3 , 6.1.4 ),
the inner shell ( 5 ) and the outer shell ( 6 ) being integrally connected to one another by a cell structure ( 7 , 8 , 9 ),
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 ),
and wherein a ring of cell channels ( 7 , 8 ) adjacent to the inner shell ( 5 ) has an approximately rectangular outer envelope outline ( 15 ) with the outer outline 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 is at a substantially constant distance from the inner outline ( 5.1 ) of the inner shell ( 5 ), characterized in that the inner outline edge sides ( 16 ) 5.1.5 , 5.1.6 , 5.1.7 , 5.1.8 ) located near the corner cell channels ( 7 ) of the ring for receiving longitudinal reinforcements ( 17 ) and a filling material surrounding them are designed such that they have a pentagonal outline with four approximately rectangular arranged pentagonal sides ( 7.1 , 7.2 ) of approximately the same length and a fifth pentagonal side ( 7.3 ) which is essentially parallel to an inner contour folding side ( 5.1.5 to 5.1.8 ), that d The clear cross-sectional dimensions of the cell channels ( 7 ) of the rim near the corner 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 pages ( 15.1 , 15.2 , 15.3 , 15.4 ), and that the clear cross-sectional dimension of the cell channels ( 7 ) close to the corner along the fifth pentagon side ( 7.3 ) is smaller than the clear cross-sectional dimension along the respective distance from the fifth pentagon side ( 7.3 ) Pentagonal sides ( 7.1 ). 2. Shaft component according to claim 1, characterized in that the cross sections of the cell channels ( 7 ) close to the corner are larger than the cross sections of the other cell channels ( 8 ) of the ring. 3. shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 1 or 2, 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 under approx. 45 ° in relation to the main inside outline ( 5.1.1 , 5.1.2 , 5.1.3 , 5.1.4 ), approximately the same length as each other, in relation to the length of the main inside outline ( 5.1.1 , 5.1.2 , 5.1.3 , 5.1.4 ) however, preferably shorter Innenumrißabkantsei ( 5.1.5 , 5.1.6 , 5.1.7 , 5.1.8 ) is formed. 4. shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1-3, characterized in that the cell structure ( 7 , 8 , 9 ) comprises a single, all-round closed ring of cell channels ( 7 , 8 ). 5. Shaft component ( 4 ) according to claim 3 or 4, 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 ) . 6. shaft component ( 304 ; 601 a, 601 b) according to claim 3 or 4, 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 inner outline main sides and the inner outline folding sides of the inner shell are each of the same length and that 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 at least a number of further cell channels ( 320 ) is seen. 7. shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1-6, 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 ( 7 ; 607 ) close to the corner of the ring each have two or three further cell channels ( 8 , 308 ) which are approximately rectangular in cross section. are arranged. 9. shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1-8, 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 ) according to one of claims 1-9, characterized in that its height is small compared to the floor height ( 1-2 ) of a building. 11. shaft component ( 601 a, 601 b) according to any one of claims 1-9, characterized in that its height corresponds approximately to the floor height of a building. 12. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1-11, characterized in that at least the cell channels ( 7 ) close to the corner of the rim are filled with a stability-increasing and / or a fire-increasing filling compound ( 18 ) . 13. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to claim 12, characterized in that the filling compound ( 18 ) is a filling compound introduced in the liquid state and then hardened. 14. Shaft component ( 4 ; 304 ; 601 a, 601 b) according to any one of claims 1-13, characterized in that at least part of the cell channels ( 7 ) filled with hardened filling compound ( 18 ) contains reinforcing bars ( 17 ). 15. Shaft component ( 601 a, 601 b) according to one of claims 1-14, 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). 16. Shaft component ( 601 a, 601 b) according to claim 15, characterized in that the connecting means of at least one end face of the shaft component ( 601 a, 601 b) projecting freely, accommodated in cell channels ( 607 ) and fixed there by hardened building material mass tion rods ( 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). 17. shaft component ( 601 a, 601 b) according to claim 16, characterized in that it in a partially filled with hardened building material cell channel ( 607 ) a free of building material mass, near the end face 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 ). 18, shaft component ( 601 a, 601 b) according to claim 17, characterized in that the free space ( 607.1 ) with a from the outer peripheral surface of the shaft component ( 601 a) outgoing filler opening ( 626 ) for the filling of curable building material mass in the free space ( 607.1 ) is executed. 19. Shaft or chimney construction manufactured using a plurality of shaft components according to one of claims 1-18 with an arrangement of longitudinal reinforcements ( 617 ) and hardened filling compound at least in the joints between at least two successive shaft components ( 601 a, 601 b) cell channels close to the corner ( 607 ).