DE7335804U - Lattice girders for reinforced concrete construction - Google Patents

Description

Lattice girders for reinforced concrete construction

The innovation relates to a lattice girder for reinforced concrete construction, in which an upper chord is connected to at least one lower chord by essentially straight struts that rise and descend at an angle to the upper chord and consist of a zigzag-shaped bent profile steel pattern that repeats itself over the entire length of the lattice girder .

Lattice girders of this type are mainly used for the production of floor slabs in semi-finished construction. Thin concrete slabs are produced as prefabricated parts.
are cast into the lattice girders with their lower chord or chords and part of the height of their struts. These thin concrete slabs can be removed after a short setting time
the formwork on which they have been poured, lift off, as the lattice girders sufficiently stiffen the concrete slabs and distribute the force applied by a hoist in such a way that
the local loads caused by the weight of the concrete slabs are kept low. Due to their low weight, the thin concrete slabs with partially embedded lattice girders can be easily transported and set down precisely at the installation site with the lifting equipment commonly used on construction sites, in order to serve as formwork for a thick layer of in-situ concrete, with which the thin concrete slab ^ up over the Top chords of the lattice girders are covered. The lattice girders

7335804 I2.oa75

1G- 43 740

stiffen the thin prefabricated concrete slabs in such a way that they can withstand the weight of the slabs even with large spans Withstand in-situ concrete.

The lattice girders are ultimately essential components of the reinforcement of the finished floor, with the struts The task of dealing with the shear stresses that occur as a result of bending loads on the floor slab between the in-situ concrete to include the existing part of the floor slab and the prefabricated concrete slab.

In known lattice girders of the type described, all struts are arranged obliquely to the top chord, namely in such a way that from one end of the lattice girder to the other, a strut follows each strut that rises diagonally to the top chord, the one from the top chord diagonally to the bottom chord or ™ if the lattice girder has two sub-straps - diagonally to your one or andsrsn lower chord descends. In other words go from nedera on the top chord provided node two of the same, zigzag shape curved profile steel consisting of struts, one of which in the direction of one end of the lattice girder, and the others descends in the direction of the other end of the lattice girder to the lower chord or one of the lower chords. If the lattice girder two lower chords on v / eist and the struts connect the upper chord with each of the two lower chords directly, so that each of the two planes running through the upper chord and one of the lower chords contains part of the struts, then can the struts in these two planes are each formed by an endless, zigzag curved profile steel snake. Round steel is particularly suitable as profile steel for each of these snakes. Upper and lower chords can also be made from round steel exist; However, profile steel with a U-shaped or tulip-shaped cross-section, for example, is also particularly suitable for the upper chord.

What is essential in all of these embodiments is a lattice girder of the genus described at the beginning - regardless of whether

7335304 iz.oa75

- * 3

1G-43 740

it is a flat or a spatial lattice girder - The feature that the endless profile steel snake or each of the two endless profile steel snakes from which di3 There are strives for a pattern that is repeated identically over the entire length of the lattice girder are bent in a zigzag shape. The economic wording of the described Semi-finished construction depends essentially on the fact that the lattice girders are manufactured in an automated manufacturing system and are therefore of any length the concrete works can be delivered.

In addition, such lattice girders for reinforced concrete construction, regardless of the length, must consist of an endless lattice girder strand have been cut out, with respect to one arranged at least approximately midway between its two ends vertical axis or plane be symmetrical. When calculating a concrete part of the described Art as a carrier- decisive shear stresses on two supports run namely on the two Λ "'supports in opposite directions Directions. A lattice girder for reinforced concrete construction must therefore be equally strong in both directions, but according to the applicable one Reinforced concrete construction theory only. those struts that do not fall towards the relevant decisive support are included in the calculation the thrust protection may be included. Struts falling to the nearest support must therefore be considered with regard to the Shear protection can be viewed as lost with all of their material content.

This could lead to the idea that it would be advantageous to remove the struts from one of the supports of a lattice girder to arrange up to its center according to an asymmetrical, for example sawtooth-shaped pattern and this pattern in the area between the center of the lattice girder and the other support by a mirror-image pattern. Such a The lattice girder would have the required symmetry in relation to the center between its two supports no strut that can be regarded as useless for the shear protection

/

-A-

would be tet, but would such a girder is not ^r ν demand match that it can be removed at any length of an endless production.

The invention is based on the object of a lattice girder of the type described at the outset, whose struts in ue ^ ug an axis * lying at least approximately in the middle between the two ends of the lattice girder is arranged symmetrically, to make such that the ratio between the total weight of the struts and their contribution to the Schubsieherung more favorable is than with known generic lattice girders.

* or level

This object is achieved according to the invention in that between two each inclined to the upper chord arranged ascending and / or descending Strive at least one at least approximately at right angles to the upper & urt extending strut is provided.

Ejη lattice girders with these 7-rf indungsmerkmalen can with the same overall dimensions and the same amount of damage for the struts significantly higher resilient than known lattice girders, which have all generic features described above and explained in more detail above. The most favorable inclination of the inclined struts of a lattice girder of the generic type in terms of shear protection is 67.5 °. If the shear load capacity of a known girder of the generic type with only struts inclined below 67.5 is set equal to 100 / ί, the shear load capacity of a lattice girder of the same size produced with the same Yierkstoifaufwam is the same 1325 *, if every inclined strut is followed by a strut arranged in the right angle to the top chord. The same result is obtained if two inclined struts are followed by a pair of struts arranged at right angles to the top chord. An even more favorable result in terms of shear load capacity is obtained if only every third strut is inclined below 67.5 against the top chord and all other struts extend at right angles to the top chord: in this case the shear load capacity is equal to

1G-43 740

However, if - which is the rule - it is clear from the start, that a lattice girder with a certain height of the upper chord above the lower chord level is built for a certain shear load capacity iioll, then reduced by the arrangement of the vine according to the invention the steel consumption for the struts in the ratio given above, i.e. by about 32% or 43%, depending on the proportion the struts extending at right angles to the top chord to the total number of struts.

The advantage that can be achieved with the invention by increasing the shear strength of the lattice girder or by saving material is even more apparent if it is not compared with the previously cheapest lattice girder described above, but instead includes in the comparison the fact that the inclination of the struts of conventional lattice girders is on average is considerably less than 67.3 ° because, for manufacturing reasons, predetermined node spacings for the different heights of the lattice girders occurring in a series of types force lower angles of inclination of the struts.

Essentially on par with the advantage described is the further, surprising advantage that the strut arrangement according to the invention additionally enables the nodal spacing on the upper chord to be reduced by half, whereby the buckling resistance of the upper chord is increased fourfold for a given cross-section of the upper chord. This in turn has the consequence that the bending strength of the lattice girder according to the invention, and thus also the permissible installation span, is correspondingly higher than with comparable known lattice girders.

With the inventive strut arrangement also the fact can be used that the lower chords tolerate larger node distances because they are at least not claimed more on wrinkles when they are embedded once in the <thin concrete slabs .ngangs described. From this point of view, it is advantageous to arrange the struts, which according to the invention run at right angles to the upper chord, between the inclined struts in such a way that the nodal distances on the lower chord or on both imaginary lower chords of a spatial lattice girder projected into a common plane are twice as large as the nodal distances on Top chord.

7335804 uoa75 ^{/ 6}

1G-43 740 - 6 -

With regard to the simplicity of manufacture and the uniformity of the node spacing on the upper chord on the one hand and on the other hand, such embodiments of the lattice girder according to the invention are generally made on the lower chords preferred in which half of all struts yich in the right Extends angle to the top chord.

Further features of the invention result from the subclaims.

The invention is illustrated below with reference to schematic drawings explained by embodiments with further details. It shows:

1 shows a section of a spatial lattice girder in side view;

2 shows an end view of the same lattice girder;

3 is a somewhat enlarged perspective view of the in Figure 1 section shown;

4 is a perspective view of a second embodiment a spatial lattice girder;

Fig. 5 shows a possible preliminary stage in the production of the in 3 shown lattice girder;

Fig. 6 shows a possible preliminary stage in the production of the in 4 shown lattice girder;

7 is a perspective view of a third embodiment a spatial lattice girder;

8 is a perspective view of a fourth embodiment a spatial lattice girder;

7335804 06/12/75

1G-43 740

Fig.9 is an end view of the one shown in 'Fig.7 or S. Lattice girder;

FIG. 10 is a front view of a modification of FIGS. 7 to 9;

Fig.11 one among other things for the production of a spatial Lattice girder according to Fig. 9 or 10 suitable level Grid;

FIG. 12 shows a modification of FIG. 11; and

13 to 15 end views of various grids according to Fig. 11 or 12 produced, essentially flat lattice girder.

The in Fig.1. to 3 shown lattice girder consists of an upper chord 12, two lower chords 14 and 14 'and a zigzag or serpentine curved profile steel 16, its straight line bounded by two successive bends Sections are hereinafter referred to as struts.

Leave the struts of the lattice girder shown in Figure 3 can be divided into four types, namely inclined struts 16a, descending from left to right connect the upper chord 12 to the lower chord 14, inclined struts 16'b, those from the left ascending to the right, the lower chord 14 'with the upper chord 12 connect, as well as struts 16c and 16'c, one or the other Connect the lower chord 14 or 14 'to the upper chord and extend at right angles to the upper chord and the lower chords. If one follows the profile steel 16 along that shown in Fig.3 Lattice girder from left to right, then repeats the sequence of struts 16a, 16c, 16'c, 16'b over and over again; the striving thus form a certain pattern that is repeated more or less often depending on the length of the lattice girder. This Despite its composition of four different types of struts, pattern shows a high degree of symmetry: One denotes the two planes in which the superstars lie as planes 18 and 18 ·, depending on whether they have one or the other sub ^ ui-t

7135104

14 or 14 'contain or touch, then the .'J tr ob ·.-No n _, r-> nun ^ in the two levels 18 and 18' is the same, provided that in 3η di <j Strcbcnanordnurig in the ITd one 18 von 11 irr. :: riGcn rc'zc, unl "__ '. · Strut arrangement in plane 18' from right to left veiuo. ^ - ;. The strut arrangement according to FIG extends at right angles to the common iLplane of the two lower chords 14 and 14 'through one of the nodes 20 or 22, at which the profile steel 16 is welded to the upper chord 12.

The strut assembly of Gittercrägcrc shown in Figure 4 comprises in addition to the occurring in Fig.3 struts los, Ibc, 16 ¹ C ¹ and 16'b two further "types of struts, namely struts 16'a, which from left descending to the right, connect the upper chord 12 to the un + chord 14 ', and struts 16b, which connect the lower chord 14 to the upper chord 12 in an ascending manner from left to right; in the lattice girder according to FIG. 4, a total of six different types of struts are provided This lattice girder also has a high degree of symmetry: the strut arrangement is symmetrical with respect to each straight line which extends at right angles to the common plane of the two lower chords 14 and 14 'through one of the perpendicularly arranged struts 16c and 16'c on the upper chord 20. In addition, the strut arrangement according to FIG on inclined struts 16a, 16b or 16'a, 16'b on the upper flange 12 formed nodes 22 extends.

The lattice girders according to FIGS. 3 and 4 have in common that on each of two inclined struts 16'b, 16a (FIG. 3) or 16'b, 16'a or 16b, 16a (FIG. 4), two struts 16c arranged at right angles , iG'c, these two struts 16c, 16'c lying in a common plane extending at right angles to the upper chord 12 and the lower chords 14, 14 '. Based on each individual cough 16a, 16c, 16'c, 16b (Fig. 3) or 16a, 16c, 16 ¹ C, 16'b, 16'a, 16'c, 16c, 16b (Fig. 4), and thus also related to the

1G-43

entire lattice girder, is half of all struts in the right Angle to the upper chord 12 arranged. Since, in addition, half of all inclined struts are taken into account in the calculation for shear resistance three quarters of all struts are in any section of the lattice girders shown in FIGS to be regarded as effective endeavors.

The lattice girders shown in Fig. 3 and 4 are despite their relatively complex structure easy to manufacture. For example, the spatial one shown in FIG. 3 results Lattice girder by the fact that the plane shown in Fig.5 Lattice folded around its central axis 24. The lattice girder shown in Figure 4 results in a corresponding manner Folding of the flat grid shown in Fig. 6. In both cases it is useful if the lower chords 14 and 14 'already are welded / edged with the steel section 16 prior to folding, the which forms right-angled and oblique struts. The upper chord 12, however, is preferably only made after the folding in both cases welded on.

The three-dimensional lattice girder shown in Figure 7, the cross-section of which can be seen in Figure 9, consists of two flat grids, which correspond to the flat grid shown in Figure 5 with the exception that the zigzag curved profile steel 16 in the one flat grid between an upper chord 12 and a lower chord 14, and in the case of the other flat grid between an upper chord 12 'and a lower chord 14'. These two flat grids are identical to each other, but are arranged in opposite directions with respect to one another, so that one grid between the struts 16c arranged at right angles has a strut 16b ascending to the right from the lower chord 14 to the upper chord 12 and the other grid between the in the right V / ^{The struts 16 1} C arranged in the legs each have an inclined strut 16'a rising to the left from the lower chord 14 to the upper chord 12 '. The two upper chords 12 and 12 'are welded together; you can also do one of the two

1G-43 740 / χ -10-

Upper chords arranged and reinforced with both welded profile steel of round or other cross-section.

However, it is also possible to produce the two flat grids, from which the three-dimensional lattice girder according to FIG. 7 is composed, initially without overbelts and to close both flat grids with a common, correspondingly more powerfully dimensioned upper belt 12 ″ only during assembly according to FIG connect, in particular to weld.

The spatial lattice girder shown in Figure 8 differs differs from the one shown in Fig. 7 only in that the two plane grids are half the distance between them a are offset from one another in the longitudinal direction. This results in despite the relatively large nodal distance a a good stiffening of the upper chord pair 12, 12 'or a single upper chord provided in its place according to FIG.

J strap 12 ".

A spatial lattice girder with the one shown in Fig. 9 or 10 Cross-section can also be composed of two flat lattice girders with the strut arrangement shown in FIG. 11 or 12 v / ground, in which the plane formed by inclined struts 16a, 16b and struts 16c arranged at right angles Pattern has pairs of directly successive, right-angled struts "Voc. While in Fig. 11 on two ascending and descending inclined struts 16b and 16a Pair of struts 16c arranged at right angles follows, is the The frequency of the struts arranged at right angles is greater in Fig. 12, because there follows each individual ascending or descending one inclined strut 16b or 16a a pair of arranged at right angles Struts 16c. The ratio of the struts 16c arranged at right angles to the total number of inclined struts 16a and 16b is so zv / ei to one.

The grid shown in Fig.11 and 12 can, instead according to Fig. 9 or 10 in pairs to form a spatial lattice

[. 7335804 12.oa75

1G-43 740

to be put together, also individually with an or
two lower chords are used and for this purpose one of the in
Fig. 13, 14 and 15 obtained cross-sectional shapes shown,
where instead of the top chord 12 made of round steel
Upper chord 12 '"made of other profile steel from, for example, U or
tulip-shaped cross-section can be provided.

CD CO LT)

Protection claims:

73358G4

Claims (7)

Protection claims Open 1. Lattice girder for reinforced concrete construction in which a top chord inclined with at least one lower chord by substantially rectilinear _i the chord and descending arranged struts according to one along the entire length of the truss multiple identical repeating pattern zigzag bent steel profile is connected, characterized characterized that between each rr.v / ei struts (leajiöbjio'a ^ ö'b) arranged obliquely to the top chord (12) at least one strut (I6c, i6 'c) provided i 2. Lattice girder according to claim 1, characterized in that half of all struts (I6a, i6b, i6'a, I6 ^! B, i6c, i6'c) extend at right angles to the upper chord (12). 3. Lattice girder according to claim 1 or 2, dessert top chord with each of two lower chords is directly connected by struts, which in each case one of two at least approximately in planes intersecting the axis of the upper chord, characterized in that all struts (I6a, i6o, 16 ^, 16 ^, 16ο, 16Ό) from a single endless profile steel (16) are formed. 4. Lattice girder according to claim 3 t, characterized in that two at right angles to the upper chord (12) extending and these with each of the two lower chords (14,14 ') connecting struts (I6c, i6'c) in a common, im at right angles to the upper belt (12) extending plane between two pairs of inclined struts (I6a, i6b, i6'a, 1b'b) are arranged. / 2 1 a - / .; ·; 7'iu 5. Lattice girder according to claim 2, the top chord of which is directly connected to each of two lower chords by struts which are each at one of zv / ei each other at least approximately in ^ l. -R axis of the upper chord intersecting planes, characterized in that the struts (I6a, 1o'b, i6c, i6 ^? C) in the two planes intersecting approximately in the axis of the upper chord (12) of two endless profile steels (16, 16 ') are formed, in which each strut (I6c, i6 ^f c) extending at right angles to the upper chord (12) is followed by only one inclined strut 6i6a, i6'b). 6. Lattice girder for reinforced concrete construction, in which an upper chord with each of two lower chords directly through essentially arranged in a straight line diagonally to the upper chord ascending and descending Striving is connected to the out / for one over the Repeat the entire length of the lattice girder several times identically the pattern are formed in a zigzag curved profile steel and in each of one of zv / ei planes intersecting at least approximately in the axis of the upper chord, in particular According to claim 5, characterized in that the two zigzag curved profile steels (16,16 ') around the Half of the distance between two consecutive rectified inclined struts (16a) in the longitudinal direction of the Lattice girders are offset from one another. 7. Lattice girder according to one of claims 1 to 6, characterized in that the at right angles to the upper belt (12) extending struts (16c, 16'c) each are arranged in pairs directly next to each other between the upper chord and the same lower chord. ' '335804 12.0R75