DE1484063A1 - Method and prefabricated part for the production of steel stone ceilings and other reinforced concrete ceilings containing hollow stones - Google Patents

Description

Expiry and production-e-part to, ierstell-, n of 2tahlsteindec'-len and sönsti, - #, en 041st - # ine abstouiden., 3ta-hlbeto # t (lick. The -crfindun # .- relates to a method for the first-iling of -.jtahlstein (Iec "-en and sonsL-i -eci, Hohlst-, ine entbalbeilden Steel batton ceilings "e.g. 3tafi-" Lbetonbalken- und -rii) pelidecl #: en with intermediate resp. j'Üllst.3i-nen in the range of nel: -ativen Moments According to the currently Provisions for the execution of IJ -'tablsteindee! -, en is, as far as the `tile ceiling cross-section the negative comments without exceeding. the permissible voltage gen cannot absorb full concrete to use. 2 as well is to be used when the shape of the feet is in the area of the negative moments an impeccable # - # ies Unterbrin, -en.the upper 3 steel inserts are not allowed. Full of concrete, which in the area of negative flashes from the upper edge goes through to the lower edge of the ceiling, each but äus. several xrünclen unfavorable, -I for the ceiling. So Ua lower the Närmeschutz the ceiling at these points, as the thermal insulation value is only about 113 of the value in the remaining area of, Dbeke is present. iiuch is the cleaning haftuhl; considerably worse than in the other places those, diQ plastered surface . is formed by Zlegel. In terms of work technology, there is the disadvantage that with full concrete a particularly tight formwork; must be applied. In addition, the ceiling egg -, #; en .-- ewich7b is considerably increased by the solid concrete. Hollow stone ceilings are therefore generally considered to be unsuitable for cases in which larger negative supporting moments reach far into the neighboring fields.

To remedy these difficulties, it is known for ceilings of this type, which are produced on a formwork, to provide the hollow ceiling bricks with lower notches in which concrete ribs are formed by casting with concrete . Thus, the top one -: - egossene concrete or mortar is chalungsboden better distributed on the S), special bricks have been developed with an additional central longitudinal cavity, through which the B, Eton or mortar is poured and which is then gdUllt with concrete In view of the fact that even when such stones are used, there is no unconditional guarantee that the concrete or mortar placed on the construction site fills the entire width of the lower icus notches, is caused by the rib formed as a result of the filling of the central longitudinal cavity, which in Connection with the outer ribs goes through from the edge to the lower edge of the ceiling, again forming a cold bridge.

For ceiling, made of hollow-cast concrete beams and clazwischeallegenden PÜllkörpern, one has, resorted in the area-the negative Niomente been the fact that most -eformte-Schaletisteine instead of lie-Genden in other ceiling area filler used be. These shell stones, which are filled with in-situ concrete to the upper edge on the construction site, can, on the other hand, consist of the same building material, e.g. fired clay, on their lower surface, like the prefabricated beams and the fillers, in the area of the positive clusters ,. and can also, if they are tragfähi-.genug, lun a SchatJ make ## Excess one superfluous. However, their use is associated with the disadvantage of a considerably poorer thermal insulation as well as a large amount of concrete and an increased weight of the ceiling. There is also the risk that the in-situ concrete will penetrate the hollow stones of the ceiling and thus transfer the poor building physics ":" lischen ## i-, properties of the solid concrete strip to the adjoining parts of the ceiling. In addition, there is the further disadvantage that these shells do not have a high section modulus and therefore often break during transport or during installation.

Special solid strips can be avoided if in the area the negative'Mom duck hollow ceilings are used, one on the whole Have butt joint that can be fully mortared at the front. According to the current regulations to be allowed to. the negative moments here, however, only with one compared to the rest Deaken cross section reduced static height can be used. This represents one This is a significant disadvantage, because, for example, a negative moment of support for the vast majority of them Support width ratios and loads is greater than the associated field moment and a reinforcement of the ceiling, which is not necessary in relation to the field moment would not be to = go if the negative supporting moment is not fully absorbed can be.

Through the foolish invention, a process can be created, the difficulties mentioned in its application and disadvantages be avoided. According to the invention, this is primarily achieved by that to accommodate the negative moments hollow stone beams with one of these moments correspondingly dimensioned pressure zone and with the cross-section of the ceiling stones or Intermediate or filler stones adapted cross-sectional shape and width with minettens the length required to cover the negative moments in one piece or in Sections are prefabricated as negative hollow stone beams and in more detail on the construction site Agreement with the locally fixed length range of the negative moments with the pressure zone at the bottom side by side or with ceilings with intermediate or filler stones in the flight of those formed from these stones in the realm of positive moments Stone fringes can be built into the ceiling.

The negative hollow stone beams can be prefabricated with a height that is lower than the height of the ceiling stones or intermediate or filler stones to be used in the area of the positive moments, and after laying on the construction site with one of the upper negative ones Embedding the concrete on top of the moment reinforcement. If a steel stone ceiling is created in this way, regardless of whether the ceiling in the area of the positive moments is formed from individual stones on a formwork or from prefabricated hollow stone beams, there is full freedom of movement in the distance between the longitudinal bars of the negative reinforcement, see above that for the formation of the negative reinforcement also prefabricated reinforcement meshes, for example welded reinforcement meshes known per se with overlapping on the gate side, can be used. This freedom of movement also exists in ceilings with intermediate or filler stones, even if the beams or ribs carrying these stones, which can also be prefabricated from hollow stones C- '), are not lower than the finished ceiling because the beams or ribs in the upper part of meis b are very narrow.

The nebative hollow bars can also be used with one of the finished The ceiling corresponds to the full height, but then with the top running Longitudinal grooves or notches, if necessary also with transverse grooves, prefabricated then the ne ## ative flower reinforcement after laying the beams be mortared within these grooves.

Further details of the invention emerge from the following Description of the embodiments shown as examples in the drawing.

The drawings show: FIG. 1 a negative hollow stone beam for a ceiling with intermediate or filling stones in the position corresponding to its installation position in a schematic view from the front and below; FIG. 2 shows a cross-section through the bar next to FIG. 1 in the area of a stone; FIG. 3 shows a cross section through the beam according to FIG. 1 in the area of a pressure-transmitting transverse rib made of concrete or mortar; FIG. 4 > a partial longitudinal section through the bar according to FIG. 1; Fis, 5 corresponding to Figs. 2 and 3 (cross-sections of Fig. 6 through a negative hollow stone beam from other Fig. 7, a partial side view of Figs. 4 and 5; Fig. 8 depictions corresponding to Figs. 59, 6 and 7 .. 9 Fig 10 gen a negative Hohlstein beam for a steel stone ceiling, Figure 11 shows another embodiment of a negative Hohlstein beam in a perspective view from the front and below; Fig. 12 is a juerschnitt by the bar of Figure 11 in the region of one of its St3ine..; Fig. 13 shows a partial side view of Fig. 12; Fig. 14 shows a further embodiment of a negative hollow stone beam for a hollow stone ceiling in the f #, cross-section through a stone; Fig. 15 shows a cross section to Fig. 14 in the area of a pressure-transmitting rib; . 16 is a partial side view of FIG 14 and 15; Fig. 17 is a perspective view of two negative Hohlstein beam formation shown in Figures 1 to 4 are prefabricated in a position in which it;... Fig. 18 two Figures 11 to 13 corresponding nega tiv-Hohlsteii% beams in their prefabrication in cross-section; -, Fis. 19 is a partial side view of FIG. 18; 20 shows a partial plan view of FIGS. 18 and 19; Moments; 22 shows a cross section and the top view of a prefabricated ceiling which is formed in the area of the all positive moments from prefabricated reinforced concrete beams and intermediate or filler stones, in the area of the negative moments; FIG. 23 'shows the ceiling according to FIG. 22 in a view from below; FIG. 24 shows a longitudinal section through a continuous prefabricated ceiling with negative hollow stone beams prefabricated in sections in the region of the negative support moments; FIG. 25 shows a schematic partial plan view of FIG. 24; FIG. 26 shows a longitudinal section corresponding to FIG. 24 with negative hollow stone bars prefabricated over the entire length; FIG. FIG. 27 shows a partial plan view of FIG. 26; 28 shows a partial top view of a continuous ceiling made of prefabricated assembly ceiling panels that are butted over a support in the region of the negative column moments, and FIG. 29 shows a partial plan view corresponding to FIG. 28 with an over a support without a joint installed ceiling plate. Shown in Fig. 1 to 4 negati "i-Hohlstein beam 1 is to HersteIlung a ceiling determined that in the area of positive torque in a known manner corresponding to FIG. 21 and the 22 from prefabricated hollow stone bar 2 (Fig. 21) or prefabricated reinforced concrete beams 3 (Fig. 22) and hollow stones, not shown, is formed as intermediate or filling stones, which are placed on the flanges 4 and 5 of the prefabricated beams 2 and 3 , referred to below as positive beams. The negative hollow stone bar 1 corresponds to the cross-sectional shape and size of the intermediate or filling stones in relation to the width and is therefore provided with lateral support projections 6 , by means of which it is placed on the flanges 4 or 5 of the positive bar 2 or 3 . The height of the negative beam 1 is less than the height of the finished ceiling and is dimensioned in such a way that a sufficiently strong concrete 7 (cf. upper and lower - coverage can be embedded by the topping.

The negative bar 1 according to FIGS. 1 to 4 consists of two zones in terms of height, namely the lower zone 99 which is provided with a small hole 12 and extends up to the height of the support projections 6 , and the upper zone lo, which for reasons of weight saving and can be provided with large air cavities 13 for easier manufacture. In the mortared and installed state of the beam, the lower zone 9, which is raised approximately to the zero line, forms the pressure zone in the negative area of the ceiling. Above this, the zone begins in the area where the stones 11 dry against one another on the front sides. A third zone of the finished ceiling, that is the zone formed by the concrete 7 (cf. Fig. 21), which has to accommodate the negative support reinforcement 8 , is produced on the construction site using in-situ concrete. Is ensured Damii a shear-resistant connection fills desan place applied topping 7, -the the laterally existing between the positive beams 2 and negative beam 1 interstices mit.den negative beam 1, the surfaces or the side faces as at 15 in Figv 1 are shown is designed asymmetrically or heavily ribbed. Are in the bottom zone 9. # Lie bricks 11, as shown in Fig. 4 indicated iot, provided with notches, the continuous in their filling with mortar over the entire width of the beam transverse ribs 16 sufficient with the use of the permissible in reinforced concrete voltages and Form a uniform width of about 4 to 5 cm across their entire height. As FIG. 21 shows, there is no straight concrete passage between the concrete 7 and the mortar transverse ribs 16 'of zone 9. Rather, the perforated stone cross-section 10 lies between these two zones, so that the thermal insulation is approximately the same at these points as well is the same as in the rest of the ceiling. The stones 11.des negative beams 1 are interconnected by a transport reinforcement 17 which is 17'eingemörtelt in a channel, which is approximately one half each in a the zones 9 and lo. The transport reinforcement can also form a precautionary element. Per cross section Iaach Fig. 2 corresponds to the cross section of « Use # 4 for deu balls after Fiel 1 eten stones. By a 7: lts le #, 2 0 'ate 44 employees xiochuüg is an edet # be't, "tilK #go; che4 BAlken ' also appears qu 5t, 6 and 7 , a negative bar 18 is shown with a cross-sectional shape which corresponds in height to the full height of the ceiling to be produced. Otherwise, however, this bar, like the negative bar 1, is also provided with support projections 6 for bearing on positive Uken 2 or 3 according to FIGS. 21 and 22. .However it consists of amount of three zones, that is, it has compared to the negative beam 1 according to Fig. 1 to 4 in addition to the zones 9 and lo have an upper stone zone 19. Its surface is at the same height as the upper edge of the ceiling. The individual stones can be laid dry or with a small joint width of 0.3 to 1 cm in zones 10 and 19 or only in zone 19 previously mortared. The negative column reinforcement must be placed in the longitudinal joints between the positive and negative beams. The pre. Part of this IL-4 version is the lower consumption of concrete on the construction site and the fact that the ceiling can be walked on immediately. The transport reinforcement 17 is mortared in two lateral reinforcement grooves 2o on the support projections 6. In addition, the stones for this negative bar in the lower zone 9 are also provided with notches for the formation of pressure-transmitting transverse ribs 16.

In Figs. 89 9 and 10 a Nef # a - '% - livbalken 2 # is shown, the height of which can correspond to the full ceiling height, but can also be lower than this, and the same for normal hollow tiles. SeeigZet's cover is made from individual stones on a formwork. The transparent reinforcement 17 is mortared in the longitudinal axis on the lower surface in a groove 231 that is open at the bottom. In this beam, too, there are transverse ribs 16 formed. Figs. 119 12 and 13 show a negative beam 22, the height of which also corresponds to the full height of the ceiling and, accordingly, of three in height like the beam according to FIGS. 5-7 Zones, namely the lower pressure zone 9, the middle new: bral zone 10 and the upper tensile zone 19. In contrast to Fig. 5-7 , however, here the entire cross-section, referred to both central axes, is completely symmetrical. The sides are designed in such a way that the same toothing is achieved both downwards and upwards, and the width of the Värsatzes steadily increases in the direction of both stressed zones 9 and 19 , so it is the largest at the beginning of zones 9 and 19 Effectiveness of the gearing is achieved. The centrally längsver14ufenden at the bottom of the groove 23 'for the transportation reinforcement 17 is located a groove 23'# n of the top of the beam against which serves to Einmörtelung the upper negative Momentenbewehrui # g, contrary are the embodiments so far described the the beams 22 forming stones at Both end faces each have a notch 24, for which purpose an approximately semicircular template cut must also be coupled to the surface of the strand during the production of the stones in the extrusion press when the crange emerges from the press with each vertically guided severing cut. Within the bar 22, the stones are alternately rotated by 180 against each other around the horizontal central axis, so that not only the central longitudinal axis runs through in alignment, but also mortar joints of exactly the same size are formed on the upper side of zone 19 and on the lower side of zone 9 # -the transverse ribs 26 which transmit pressure and tensile forces when they are filled with mortar. In the Bergtellung the negative bar both the lower Längenut 23'jait, the Tranavortbewehrung than also be mortared the lower transverse joints, while the upper longitudinal groove 23 and the * #uerausklinkungen top 24 for the insertion of the upper negative column reinforcement and optionally also the ## uerbewehrung and remain open for concreting on the construction site. However, there is also the possibility of combining the negative beams according to the invention into larger ceiling panels before they are used, if the construction, such as in assembly construction, requires more extensive prefabrication. In this case, all pulls or grooves are cast beforehand and the negative support reinforcement is mortared in accordingly.

149, 15 and 16 show a negative beam 27 with the full height of the ceiling for hollow stone ceilings, which consist of statically co-operating stones with partially mortarable butt joints and are produced on a formwork. Here, too, as in FIGS. 11-13, the stones are symmetrical with respect to both central axes. In this way, both the pressure zone and the tensile zone can be connected to one another in a pressure-resistant or tensile-resistant manner and to a certain extent also in a shear and shear-resistant manner with one stone mold. The transport reinforcement 1? In this embodiment, similar to FIG. 1-49, it is mortared in a completely closed channel 17 which is not visible to the outside.

.v 9 In FIG. 17 , two negative bars 1 corresponding to the embodiments according to FIGS. 1-4 and 21 are shown during prefabrication. The stones 11 are placed on the production floor (not shown) in such a way that their lower surfaces point upwards. The notches used to form the transverse ribs 16 are exposed from above to be filled with concrete or mortar. Here, the circular channel 1 ', in which the transport reinforcement 17' is located, is completely or partially filled with mortar. If the transport reinforcement is not completely covered by mortar in the middle of the stone length, this is of no importance, since this reinforcement only needs to be effective for holding the stones together until after they have been laid. It can, therefore, only a small # uerschnitt liaben, about 0 3 bis..6 mm. In FIG. 17 , the beam 1 is shown on the left-hand side before the concrete or mortar pouring, while the right-hand side shows the beam with the transverse ribs 16 that is already ready for turning and laying. The production of the negative bars in this way is expediently carried out in series for certain lengths that are a multiple of the stone length, directly next to one another and in stock. Experience has shown that the length of a solid strip to absorb v & n negative moments in a slab running over a column with two fields of approximately the same span must be approximately 1/6 of the span of the adjacent span. That bedded at a con- continuously stretched over two fields ceiling in 'one Residential buildings with spans of ti # m 4, oo m and '2 M 5900 mg daso the Igassivatritt on the left side of the support 59 0983 M and on the right side 491 - o, 66 m long If the stone length is assumed to be 25 cm, then for the left 7field four-stone, i.e. 1.0 m long negative beams and for the reohte field three-stone, i.e. o975 x long Nesatt v13alken would have to be made or be taken from the stock pile. If, on the other hand, the MaS3ivstrip can be guided over the support in one piece, the total length would have to be 0.83 + 0166 m 1.49 m. This corresponds to a six-stone - 1.50 m long negative bar. The smallest length is two-stone beams and is SOM4t 50 cm, while the largest length for reasons of weight should not exceed eight-stone beams, ie 2.0 m long beams. Such a negative beam weighs about 60 to 80 kg and can still be laid by hand by two men.

FIG. 18 shows two bars 22 according to FIGS. 11 to 13 in the prefabricated position in cross section. The longitudinal groove 23 ' receiving the transport reinforcement 17 is at the top, so that the reinforcement can be inserted from above and the groove 23 1 can be well potted. Likewise, the -, #, uerrippen 16 can be concreted in a simple manner from above, whereby they can be limited on the sides, for example, by rectangular timber frames 26. The bar 22 shown on the left in FIGS. 18 and 20 is not yet grouted, while the right bar 22 has already been concreted.

As already mentioned in connection with Fig. I to 4, the nega-, 1U, ivbalken 1 in Fi. 21 in cross-section through C a mortar transverse rib 16 and in the A-nsich - "-. The prefabricated ceiling shown from below is designed in two zones, ie they only consist of the lower pressure zone Q and the neutral zone 10. The negative bar 1 and the positive beam 2 are only so high that there is still sufficient space to the upper edge of the finished ceiling to be able to arrange the upper negative column reinforcement 8 with small mutual spacing of the reinforcement, bars and perfect concrete cover Wall of the stones, which can also have the opposite inclination, and the position of the stones rotated by 180 0 , the aforementioned toothing is formed and achieved at 15 , so that the compressive force from the stones on the in-situ concrete between the negative beam 1 and the positive beam 2 is properly transferred.

22 and 23 show a ceiling formed from the positive reinforced concrete beams 3 and the prefabricated negative beams 29 in cross-section - through the transverse ribs 16 of the negative beams and in a diagrammatic view from above and below. In contrast to FIG Negative bars 29 are designed with three zones, that is to say, apart from the lower pressure zone 9 and the neutral zone 10 , they also contain the tension zone 19. They therefore correspond to the full ceiling height. To accommodate the upper negative reinforcement 8 , they are provided with upper longitudinal grooves 30 and notches 31 . Since the positive balls 3 have a lower height than the finished ceiling and the negative beams 29 have two upper longitudinal grooves 30 at a short distance from one another, the upper negative support reinforcement can, if desired, be arranged in the form of welded reinforcement mats known per se. The grooves 23 for the transport reinforcement 17 are located exactly under the upper grooves 30 of the negative beams.

In Fig, 24 is a longitudinal section in the region of the negative torque supports is shown a ceiling, which, as seen ISTL 33 of any type and made of prefabricated in sections negative bar 34, consists of Fig. 25 from beam 35. Positive. The P # s #, - tivbalken 33 and the NegativbalkäustÜcke 34, 35 are not in alignment in both fields, but are arranged offset from one another and abut on the support 32 formed by a wall or a joist.

The Negativbalkenstüc10349 35 are here, for example , two-zone in accordance with FIGS. 1 to 4 or 21, while the third zone, ie the tensile zone, is formed by the cast-in-place concrete 7 in which the upper Negativbeverung 8 is embedded.

FIG. 26 shows a longitudinal section, corresponding to FIG. 24, of a ceiling, the negative beams of which, however, are designed with three zones, ie have a lower pressure zone 9, a middle zone 10 and the upper tensile zone 19 . In addition, the negative bars 36 each consist of one piece and run through the support 32 . The positive bars 37 are therefore also in alignment in both fields. You have hit the support 32 .

The invention can also be used if the degree i; i range of positive moments instead of on the construction site from individual hollow stones or individual prefabricated beams and Uischen or. Filling stones are formed from contouring plates which are prefabricated from the parts mentioned. Two embodiments of ceilings of this type are shown in partial plan view in FIGS . 28 and 29. v 0 to Fig. 28 is formed to cover the positive area of Yelder both sides of the support 32 by mounting ceiling panels 38, the Füllsteinreihen lying from the position indicated by the lines striohpunktierten positive beams 39 and between these are 4o prefabricated. The mounting plates 38 are butted on the central support 32 and provided with cutouts 41 at the butt ends, into which, after the mounting plates have been laid, negative bars 42 are inserted, which pass through the support 32. The negative bars 42 and the positive bars 39 of the mounting plates 38 are, as in FIG. 27, in alignment. The longitudinal section through the ceiling according to FIG. 28 corresponds to FIG. 26. The negative beams 42 are also expediently three-zone and made with the negative column reinforcement and the grouting, so that reinforcement no longer needs to be installed on the construction site.

The embodiment of Fig. 29, for example, a bar plate auskrageildela represent kanni corresponds substantially to the Fig. 28, here, only are the Vontageplatten 43, only one of which is shown continuously formed on the support 32. Since the negative bars 42 also pass over the support 32 , they can also be used in their recesses 44 during the prefabrication of the mounting plates 43.

Claims (1)

P A T E N T A NS PR Ü CH E Process for the production of steel stone ceilings and other reinforced concrete ceilings containing hollow stones, e.g. B. reinforced concrete beam or ribbed ceilings with intermediate or filler stones, in the range of negative moments characterized in that to accommodate the negative moments bars made of hollow stones or other stones with a pressure zone corresponding to these moments and with the cross section of the ceiling stones or intermediate or . Filling stones of adapted cross-sectional shape and width in at least the length required to cover the negative moments, prefabricated in one piece or in sections as negative hollow stone beams and in exact accordance with the locally defined length range of the negative moments with the pressure zone lying next to one another or in the case of ceilings with intermediate or filler stones in line with the rows of stones formed from these stones in the area of the positive moments are built into the ceiling. Method according to claim 1, characterized in that the negative hollow stone beams are prefabricated with a height which is less than the height of the finished ceiling, and after laying in a manner known per se on the construction site are provided with a concrete topping in which the upper Negative reinforcement is embedded. Method according to claim 29 dg9 that the upper negative reinforcement is embedded in the form of prefabricated reinforcement mats, for example welded reinforcement mats known per se. Method according to claim 1, dg9 that the negative hollow brick beams are prefabricated with a height fully corresponding to the finished ceiling and the negative reinforcement is concreted or mortared on the construction site in longitudinal and possibly transverse grooves of the beams. Method according to one of Claims 1 to 4, characterized in that the negative hollow stone bars are prefabricated with their upper surface in the finished ceiling resting on the production floor. Method according to one of the claims 1, 3 or 59, in which the negative hollow concrete beams are prefabricated in sections and are made of positive prefabricated beams and intermediate or intermediate beams to form a ceiling running over a support. Filling blocks are used, characterized in that the sections of the negative hollow stone beams are placed on both sides of a wall part or beam forming the support, offset from one another transversely to their longitudinal direction, between the positive prefabricated beams, which are also offset from one another on the support, and through concrete and embedding of the Negative reinforcement are connected to each other and to the prefabricated beams. Method according to one of Claims 1 to 69, characterized in that the negative hollow concrete beams are built into the ceiling together with prefabricated thin assembly cover plates dimensioned for the positive moments. Method according to Claim 7, characterized in that the assembly ceiling panels are pushed over the support. Method according to Claim 79, characterized in that the assembly ceiling panels are guided continuously over the support. Method according to claim 99, characterized in that the negative beams, for example for the formation of balcony cantilever plates, are already built into the assembly plates when they are prefabricated. Pre-fabricated beams from stones, preferably hollow stones, for the production of steel concrete ceilings and other reinforced concrete ceilings containing hollow stones or other stones, e.g. reinforced concrete beams or ribbed ceilings with intermediate or filler stones, characterized in that it is a negative beam (it 189 219 229 279 291 349 359 369 42) is designed with a lower pressure zone (9) dimensioned to absorb the negative moments of a continuous or clamped ceiling and at least one second zone (10) above it and a cross-sectional shape that corresponds to the cross-section of the ceiling stones or intermediate or filler blocks -width and a length corresponding to the course of the negative moment line. Negative bar according to Claim 11, characterized in that its pressure zone (9) extends approximately to the zero line. Negative beam according to claim 11 or 12, characterized in that it is provided with a tension zone (19) above the second zone (10). Negative beam according to one of Claims 11 to 139 dg, in that it is formed from hollow brick bricks. Negative bars DG according to any one of claims 11 to 149, that seine.Steine (11) in the region of the print zone (9) of an in t he apannrichtung verlaufendexr small holes g12) possess # in the second zone (10) but with large air cavities (13) are provided. Negative bar according to one of Claims 13 to 159, characterized in that its stones (11 ) also have small perforations (14) in the tension zone (19). Negative beam according to one of Claims 11 to 169, characterized in that it has an inner longitudinally running mortar channel (17 ') in which the transport reinforcement (17) is embedded. i # egativbalken according to claim 17, characterized in that the mortar channel each is located (17 ') of the height to about half in the lower pressure zone (9) and the overlying zone (10). Negative bar according to any one of claims 11 to 16, characterized in that in the pressure zone (9) it has at least one downwardly exposed longitudinal mortar groove (23 ') in which the transport reinforcement (17) is embedded. Negative bar according to one of claims 11 to 19, characterized in that its stones (ii, at least in the area of the second zone (10) are provided with a beveled side surface (11 ') with the other side surface of the respectively following one 1800 turned stone forms a toothed shoulder (19) . Negative bar according to one of Claims 11 to 20 with three zones lying one above the other, i.e., its. Stones (11) in the upper tension zone (19) are provided with longitudinal grooves (23) which lead to Negative beam according to claim 21 with mortar grooves containing the transport reinforcement according to claim 18 or 199 dg9 that the longitudinal grooves (23) serving to accommodate the negative moment reinforcement are exactly opposite the mortar grooves (231) for the transport reinforcement. Negative beam according to one of claims 11 to 229 dg. that its stones (11) are provided with a notch (241) in the area of the pressure zone (9) at least on one end face, in which each has a pressure-transmitting transverse rib (16) made of concrete or mortar that extends over the width of the stone. Negative beam according to one of Claims 21 to 239 dg, that its stones (11) are also provided in the area of the tension zone (19) on at least one end face with outlines (24) to form transverse grooves (25) open at the top. Negative beam according to one of Claims 13 to 24, dg that it contains the negative moment reinforcement (9) already grooved in the tensile zone (19). Negative bar according to claim 259 dgp that it is prefabricated in connection with an assembly ceiling plate (43) prefabricated for the positive torque range. Over one or more supports continuous steel stone ceiling, dgq that it is provided with negative beams (19 189 21, '229 27.9 299 349 359 369 42 ) according to one of claims 11 to 26 in the area of the negative column moments, which are aligned in the area of the positive moments arranged rows of stones are arranged side by side. Reinforced concrete ceiling running through one or more columns with intermediate or filling stones, dg. that it is provided in the area of the negative column moments with negative beams (19 18, 219 229 27, 299 349 359 369 42) according to one of claims 10 to 25 , which are aligned in the area of the positive moments of the intermediate or Front rows formed by filling stones are arranged. Ceiling according to claim 27 or 28, dg that the negative beams (35) are abutted on a support (32) formed by a wall or a joist and are offset from one another in the ceiling fields on both sides of the support (32) transversely to their longitudinal direction 29p dge that in the area of the negative moments it has an upper tensile zone made of in-situ concrete M which contains the negative reinforcement (8) . Ceiling according to claim 27 or 28, dgq that the negative plates (42) run through the support (32) and are provided with an upper tension zone. Ceiling according to one of Claims 27 to 319 dg9 that its upper negative reinforcement is formed by a prefabricated, eg wax-welded reinforcement mat.