DE371180C - Process for the manufacture of reinforced concrete structures - Google Patents

Description

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ISSUED
MARCH 12, 1923

REICH S PATENT OFFICE

PATENT LETTERING

CLASS 37a GROUP 5

(W§2014

Rudolf Winternitz in Vienna.
Process for the production of reinforced concrete structures.
Patented in the German Empire on February 7, 1919.

The present invention is a further development of the known concept of components Manufactured from reinforced concrete in horizontal formwork regardless of the construction site. Such components have already been used to produce buildings, by the walls are made with the help of ready-made studs and for the ceiling beams from these Has used separate parts that form a frame with the stands in place had to be connected. This construction has the disadvantage that this combined support body cannot be calculated with certainty, since it cannot be determined whether after the connection of the individual parts

! lying or a clamped ceiling beam is present, so that either the dimensions of the Both the stand and the beam are too small or, if they are too strong, they are useless Waste of material occurs.

Frame-like girders have also been used for the construction of structures in such a way that that you have made the whole frame with the help of a standing formwork or nesting on the spot. Tensions occur as a result of the shrinkage of the concrete in the frame, which is caused by stronger Dimensioning of the cross-sections must be compensated, eliminating a certain waste of fabric entry.

In contrast, according to the present invention, buildings from outside the building | Platzes manufactured components from reinforced concrete j erected in such a way that stiff reinforced concrete S frame without standing scaffolding and formwork can be built as a scaffolding in such a way that their Legs form the wall posts and their crossbars form the ceiling beams and roof beams. That has the advantage that all lanyards

-ίο between stand and. Ceiling beams superfluous you also gain greater static clarity because the calculation of all dimensions the rigid frame can be done with sufficient accuracy. It can also be demonstrated that the Shrinkage in the frame produced standing in the building is far more disadvantageous than in previously created and hardened frames. This peculiarity is evident in the new frame made in horizontal formwork

ao men applies due to the lower tendency to form cracks and gives the option of reinforcement to be measured with the greatest thrift.

Embodiments of the new construction are shown in the drawing, namely Fig. 1 shows a whole house in cross section with the arrangement of the frames in the floors and in the attic, Fig. 2, 3 and 4 special designs of the frame. As can be seen in Fig. 1, rigid frames made of reinforced concrete are used for the structure, regardless of the construction site; these frames show the shape of a yoke, 'which consists of the legs or stems α and b and of the bar c. These three-legged frames can be formed from one piece, but they can also be assembled from two U-shaped parts.

These frames are installed without standing formwork or equipment in such a way that

that the legs α and b serve as posts for the walls and the bars c as a ceiling beam. As Fig. 1 shows, the frames can be stacked on top of each other, whereby the frame with the outside sloping

standing thigh and for the uppermost part. of the roof those with a sloping ledger are taken. In these, the outer leg has been shortened or left out entirely. The leg legs α and b of the ground floor are fastened in such a way that they protrude into suitable recesses in the foundations or are connected by a subsequently cast reinforcement projecting into the foundation and the stem. In the

In the last-mentioned manner, the stems of the higher storey are also matched with those of the floor below.

The distances between the frames are chosen so that the space between the windows and door openings, while the span of the frame is expediently dimensioned that it corresponds to the dimensions of a living room.

The room closure can be done in various ways, for example by the fact that on the inner or outer side, or on both sides of the posts, concrete planks, cement slabs o. The like. Be attached, or that a filling masonry is introduced between the posts.

The ceiling is produced in such a way that ceiling planks are placed on the transom c of the frame placed directly or with the use of sound and heat insulating means and be fastened in the usual way; likewise, the roof frame is attached to the rafter-like bars Planks are placed that overlap like roof tiles and form a weatherproof seal. Through these roof planks in the Together with the ceiling planks, there is a rigid connection between the individual frames produced so that a special longitudinal association can be omitted.

According to Fig. 2, the frame is closed in the lower part by a cross bar c ¹ . When installing such frames in the building, these lower crossbars c ¹ also serve as ceiling beams for the lower storey, for example the basement below.

Fig. 3 shows the design of the profile frame in such a way that cantilever-like projections f are present in continuation of the bolt c, which allow a use of the frame in such a way that the ends of the projections rest on beams B; this has the advantage that a larger stem spacing is achieved and accordingly a space with a wide post spacing can be created.

Fig. 4 shows the connection of two frames A ¹ and A ² by crossbars g \ g ² to form a spatial structure that is formed in one; Both open and closed frames can be used, with the latter indicated by dashed lines in the figure. Trap also below crossbars g ³ , g ⁴ are arranged. .

Claims (1)

Patent claim: Process for the production of reinforced concrete structures, characterized in that Ready-made rigid reinforced concrete frames are built up as scaffolding in such a way that their legs meet the wall posts and their crossbars hand over the ceiling and roof racks. 1 sheet of drawings.