EP2410097A2 - Butt joints of highly stressed prefabricated columns - Google Patents

Abstract

The joint has high strength reinforcing steel bars (5, 8) obtusely pushed together without direct contact. The distance between the reinforcing steel bars of a lower precast concrete column (1) and an upper precast concrete column (7) amounts to one by eighth of a single rod diameter plus a tolerance compensation. A lower edge of the upper precast concrete column is formed against a horizontal bent. The upper precast concrete column is fitted with a baseplate on an end of the one of the reinforcing steel bars.

Description

Technical area

The invention relates to the butt joint of highly loaded reinforced concrete prefabricated columns.

State of the art

In the construction of high-rise buildings, it is customary to form supports as composite supports. Here, steel profiles are poured into concrete so that a common supporting effect of concrete and steel is created. These are heavy steel construction with welded profiles, which cause relatively high material costs. Another disadvantage is that the composite construction compared to the precast construction requires significantly longer construction times and thus generates a further cost disadvantage.

Alternatively, reinforced reinforced concrete columns can be created. Here, the reinforcement of reinforced concrete columns with high-strength steel is particularly advantageous for heavily loaded columns with predominantly normal force load - the steel is fully utilized in its carrying capacity. In particular, in connection with the large number of columns in high-rise buildings, the resulting reduction of the cross-section has a positive effect: the planning of slender columns makes the usable area larger and thus provides an economic benefit.

It is also common to use precast columns - these prefabricated in the factory components are characterized by a high dimensional accuracy. The transfer of the finished parts is done with the crane. Time-consuming set-up times for the conversion of formwork elements or long-term reinforcement work and concreting on site can be omitted.

A disadvantage of the construction methods mentioned is that blunt shocks of the finished parts can be realized so far only at low loaded columns. In all other cases, the reinforcement of the columns must be connected to that of the columns of the previous floor or of the underlying component: in situ concrete, this can also be done by overlapping lengths after standardization, otherwise suitable reinforcement connection means are used. Commonly used are threaded sleeves or clamped connections. The disadvantage is the high expenditure of time that arises from the fact that every single connection of two reinforcing bars must be carried out manually; the prefabrication of reinforcement baskets is only possible to a limited extent. In addition, the reinforcement sleeves require a certain amount of space, since the circumference of the sleeve significantly exceeds that of the reinforcing rod. This fact alone limits the number of installable reinforcing bars in cross-section, because a sufficient embedment in the cement matrix is a prerequisite for the load-bearing behavior of the composite reinforced concrete.

With a variety of reinforced concrete columns in the structure, the production of the columns is often on the critical path - d. H. The manufacture of the columns defines the duration of the construction period.

Object of the invention

The object of the invention is to provide a system which makes it possible within a short construction time to create heavy-duty reinforced concrete columns in high quality execution - and so to optimize the economy in the production and quality, especially of high-rise buildings.

Presentation of the invention

The object is solved by the features specified in the characterizing part of claim 1.

For this purpose, the invention provides, preferably with high-strength steel reinforced precast columns blunt and only separated by a thin mortar bed separated from each other.

Due to the very high steel stresses, the usual transmission of forces from the reinforcing bar via composite in the concrete and continue on the mortar joint is not feasible. It would come to concrete failure due to the occurring transverse tensile stresses in the load transition area at the column end. Even the mortar in the joint can not transfer the entire support force alone. The formation of two load bearing effects is necessary: the power transmission between the bars through the mortar and from bar to bar directly. The force in the reinforcing steel must be transferred to the continuing reinforcing steel via peak pressure. This can be achieved via a contact impact, if the rods are directly above each other. In terms of construction, however, this is hardly practicable when using precast columns, and the tolerances in the construction industry do not permit a planned contact impact. Surprisingly, it has been found that the impact of two highly loaded precast columns in the embodiment of the invention quite well withstand the stresses and forwards the occurring effects with sufficient security. It can be on a direct contact of the steel inserts - is used for the preferred high-strength steel - are omitted, these are within the usual tolerances on the site with a scheduled distance from each other by about 5 mm - maximum 1/8 of the steel diameter of the individual reinforcing bar - (+/- 2 mm tolerance) arranged and adjusted. The distance between the concrete of the pillar prefabricated parts and the concrete ceiling and the reinforcing bars projecting beyond each other is poured out with grout with grout. It turns out that under these geometric boundary conditions in the relatively thin mortar bed, the effect of multiaxial stress state in the mortar joint increases the load-bearing safety of the grout and the overall performance is very good.

A prerequisite for the force transfer in the butt joint is that the reinforcing bars made of steel - conventional reinforcing steel S500 or high-strength steel - are geometrically in one axis. This is inventively ensured by the fact that in the factory-made precast concrete fitting dowels are installed, which serve the adjustment and alignment of the connection.

• Fig. 1: Schnitt durch den Stützenstoß im Deckenbereich
• Fig. 2: Draufsicht auf einen Stoßquerschnitt - Prinzipskizze
• Fig. 3: Schnitt durch den Stützenstoß im Deckenbereich mit verstärkender Stahlplatte - Ausführungsvariante

Exemplary embodiments are illustrated in the drawings and are described in more detail below:

• Fig. 1 : Section through the buttress joint in the ceiling area
• Fig. 2 : Top view on a push cross section - outline sketch
• Fig. 3 : Section through the column joint in the ceiling area with reinforcing steel plate - variant

In FIG. 1 is a vertical section through the joint area shown, as an example, the reinforcement 5, 8 is shown simplified. This must be inserted according to the requirements of the action according to the design.

First, the supports of the lower floor 1 are provided and the reinforced concrete ceiling 3 is concreted on the upper edge of the finished parts 2. Over the top edge 4 of the Ortbetondecke 3 the reinforcing bars 5 protrude about 20 to 40 mm out. In addition, at least one - preferably two or more - Justierdollen with sleeve 6, 10 already installed in the production of finished parts. In the production of prefabricated columns in the factory is to ensure a high dimensional stability with respect to the position of the reinforcing bars 5, 8 and the adjusting tools 6, 10.

The precast columns 7 of the next floor are placed and aligned by means of the adjusting elements 6, 10. The reinforcement 8 of the prefabricated reinforced concrete elements 7 protrudes at its lower edge 9 approximately 10 to 25 mm, the distance between the precast lower edge 9 and upper edge 4 of the Ortbetondecke 3 is about 50 mm or more. The space between the support lower edge 9 and Ortbetonoberkante 4 is poured together with the joint between the reinforcing bars 5, 8 non-positively with low-shrinkage grout 11. In an alternative embodiment, the lower edge 9 of the pillar finished part 7 is inclined - this is particularly advantageous in terms of the complete filling of the mortar joint with grout 11th

In FIG. 2 is the stump stump invention to see in a plan view. To recognize here is a possible arrangement of the reinforcing bars 5, 8 and the Justierdollen 6, 10 in plan view.

FIG. 3 shows the alternative embodiment of the precast support 7 with built-in base plate 12, which is preferably made in steel. Their arrangement creates a multi-axial bearing effect on the column foot and summarizes the transverse tensile stresses occurring there. This is a particularly robust construction of the stump stump joint according to the invention. In this variant, the reinforcement of the lower support 1 projects about 40 to 55 mm beyond the upper edge 4 of the concrete ceiling 3. The Justierhilfsmittel 6, 10 provide an exact location of the reinforcing bars 5, 8 in their axial extension. The mortar joint is also pressed with potting mortar 11. Since this exemplary embodiment of the invention proves to be much more robust, here is a distance between the upper end of the bar steel 5 and lower edge of the Steel plate 12 of up to a quarter (1/4 d _s ) of the diameter of the single rod possible.

In general, reinforcements at the bar end 8 serve to improve the robustness of the column connection. As an alternative to the steel plate 12, embodiments with steel ring inserts around the ends of the reinforcing rods 8 are also advantageous.

LIST OF REFERENCE NUMBERS

1

Prefabricated columns lower floor

2

Top edge of finished part

3

Reinforced concrete floor

4

Top edge of reinforced concrete ceiling

5

Reinforcement in the lower finished part

6

Adjustment sleeve in the upper finished part

7

Prefabricated columns upper floor

8th

Reinforcement in the upper finished part

9

Lower edge of upper finished part

10

Adjusting wheels in the lower finished part

11

mortar bed

12

footplate

Claims (8)

Execution of a shock of highly loaded prefabricated concrete supports (1), (7) preferably made of reinforced concrete,
characterized in that the reinforcing steel bars (5), (8) are butted together without direct contact. Device according to claim 1,
characterized in that the distance between the reinforcing bars (5) of the lower precast prop (1) and the reinforcing bars (8) of the upper precast prop (7) is at most 1/8 of the single rod diameter plus the tolerance compensation. Device according to at least one of claims 1 and 2,
characterized in that the mortar bed (11) between the upper edge (4) of the Ortbetondecke (3) and the lower edge (9) of the precast support (7) at maximum horizontal edge is a maximum of 50 mm thick. Device according to at least one of claims 1 to 3,
characterized in that the lower edge of the precast support (7) is designed to be inclined to the horizontal and the mortar bed (11) between the upper edge (4) of the Ortbetondecke (3) and the lower edge (9) of the precast support (7) on one side thicker than 50 mm can. Device according to at least one of claims 1 to 4,
characterized in that the upper precast support (7) is provided with a foot plate (12) on which the reinforcing bars (8) terminate dull. Device according to claim 5,
characterized in that the distance between the reinforcing bars (5) of the lower precast prop (1) and the base plate (12) of the upper precast prop (7) is at most 1/4 of the single rod diameter. Device according to at least one of claims 1 to 6,
characterized in that the reinforcing steel (5), (8) is a high-strength reinforcing steel. Device according to at least one of claims 1 to 7,
characterized in that in the factory-made precast concrete parts precisely (10) and sleeves (6) are installed, which serve the adjustment and alignment of the terminal.

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