EP1253259A2 - Reinforcing rod of fiber reinforced plastic - Google Patents

Abstract

The rib flanks (4, 14) forming the transition regions between the rib vertices (3, 13) and grooves (2, 13) in between the ribs have an angle of more than 45 deg. relative to the bar central length axis (5). The axial rib width (A) is greater than the axial distance (B) between adjacent ribs by at least half the rib height (H), defined by the equation H/2 = 1/2 x (D-d)/2, where d is the bar diameter in the rib vertex region and D is the diameter in the groove region.

Description

The invention relates to a reinforcement bar made of fiber-reinforced plastic its circumferential surface provided with a radially opposite the rod surface outwardly protruding profiling in the form of itself at least over part the circumferentially extending ribs and / or with respect to the rod surface radially inwardly extending recesses, in which case the radial external rod jacket areas that extend over at least part of the circumference form extending ribs.

In the past, studies have been carried out time and again to find out for certain Applications an alternative to the conventional reinforcing steel or stainless steel to create existing metal bars. A major incentive for tests with plastic reinforcement bars lies in the lower thermal conductivity certain plastics (such as polyester, vinyl ester, etc.); also let different types of fibers such as glass, aramid and other fibers the tensile strength and thus the stability of the reinforcement bar very exactly that adapt the respective application.

A major problem with the known plastic rods, however, is that Profiling, which in contrast to the ribbed metal reinforcement bars, is not satisfactorily creates a resilient bond with the Plastic reinforcement bar to enter surrounding concrete. Because usually radially outwardly projecting ribs formed from the surface of the rod shear off even at relatively low axial tensile loads, since they themselves are not stable enough in the ribs with reinforcing fibers displaced into them, the forces acting on the axial reinforcement of the reinforcing bar surrounding concrete in the reinforcement bar or vice versa. Accordingly, the ribbed plastic reinforcing bars have none in practice sufficient bond properties.

On the other hand, with sufficiently flat ribs that do not shear, the danger that they will experience a so-called split pull failure with them Reinforced concrete component caused by the form-fitting similar to a wedge the ribbed reinforcement bar surrounding concrete in tensile loads expose to an ever increasing rod circumference and finally - if so the plastic ribs are not sheared beforehand - burst open. Starting from the hole in the concrete formed by the reinforcement bar there is a crack until the hole diameter together with the crack gap is large enough that the reinforcement bar together with the ribs be pulled out of its original position in the axial direction can.

Proceeding from this, the present invention is based on the object to provide fiber reinforced plastic reinforcement bar, its ribs are sufficiently stable to shear them off under the usual rod loads to prevent and on the other hand, the effect of split tension failure avoids.

This object is achieved in that the transition area between the radially inner rib base with diameter d and radial external rib apex area with diameter D forming lateral Rib flanks at least in partial areas with an incline of more than 45 ° have the rod axis, and that the axial width of the rib areas with at least half the rib height ½ x H = ½ x (D-d) / 2 is greater than the axial distance between the rib areas having at least half the rib height two adjacent ribs.

The obtuse angle of the rib flanks prevents the rib flanks from being prevented and the ribs themselves act like a wedge and the reinforcing bar Detonate the surrounding concrete. Rather put the rib flanks in their obtuse-angled areas a support surface available, which is in axial Support tensile loads axially on the concrete without the radial gradient component can cause the damage mentioned.

The second characteristic refers to the stability of the ribs: if with Put simply, the rib is wider than the concrete between two Ribs, then it can be assumed that the ribs are also sufficient are stable to withstand the usual tensile loads. Here is the Compound with the radially inner rebar on such a large area effective that the ribs cannot be sheared off.

The rib base R is expedient, that is the axial width of a rib including the axial widths of the two lateral adjacent rib flanks, larger than the concrete bracket base B, that is the axial width of an unribbed one Rib base including the two laterally adjacent rib flanks. This assumption is also based on the knowledge that a large Bond area between rib and reinforcement bar with a smaller one at the same time Bonded area between the concrete bracket and the adjacent concrete the stability conditions fail to shear the ribs reliably can be prevented.

As for the design rules mentioned, these are particularly important to be used if the ribs have a rib height H = (D-d) / 2 similar to reinforcing steel on the order of D / 30 to D / 7.

Finally, a rib pitch T is recommended, which is comparable to a wavelength the axial width of a rib including the two laterally adjacent Rib flanks plus the axial width of an adjacent non-ribbed rib base, on the order of between 1/3 x D and 2 x D.

The present invention can be applied to any plastic and fiber materials use, especially with glass fibers and / or carbon fibers. Conveniently, the reinforcing fibers are also shifted into the ribs so that the connection of the ribs with the reinforcement bar underneath in the sense of a greater tensile strength is improved.

As far as the shape of the ribs is concerned, they expediently run in a helical shape around the bar circumference, inclined to the bar axis and deviating from the perpendicular to the bar axis.

In particular, however, it is also within the scope of the invention to "negatively" the ribs to produce, that is, an un-ribbed surface of the rod with local radial depressions to provide. In this case, the depressions each form the radial one inner rib base, while the radially outer rod jacket areas the ribs or the rib apex regions in the sense of the present invention represent.

The invention is described once again below with reference to FIG an axial section shown in the accompanying Figure 1 through the halves of two reinforcement bars according to the invention.

The ribbed reinforcing bar 1 shown in Figure 1 has several evenly Radially inner rib base sections 2, 12 distributed over the rod circumference on and relative to these sections radially outwardly projecting ribs 3, 13, the transition region between the outer rib apex regions with diameter D and the inside rib base sections with Diameter d are formed by lateral rib flanks 4, 14 which have an incline have in relation to the rod axis 5 in the form of an angle α, β of more than 45 °. The rib apex regions 3, 13 are made in both exemplary embodiments Figure 1 formed smooth cylindrical. But it would also be possible to form the rib apex areas curved and seamlessly into the adjacent To let rib flanks pass over.

In addition to these obtuse-angled rib flanks, at least in parts The following are essential dimensions of the reinforcing bar 1: The rib height H is calculated from (D-d) / 2. Those rib areas that are at least half Have rib height (or a larger rib height), extend over a axial width A. Between such rib areas with at least half the rib height there is a distance B. According to the present invention, it is now prescribed that that A> B must be, whereby the stability conditions mentioned, in relation to the axial cut, a wider "rib tooth" than "concrete tooth" results.

The following assumption is easier to use and is also valid: The rib base R, that is the axial length of a radially outer rib apex region 13 and the two adjacent rib flanks 14 must be larger be than the concrete console base B, that's the axial width of an unribbed one Rib base 12 including the two laterally adjacent rib flanks 14th

Furthermore, the rib height H, which is calculated from (D-d) / 2, should be of the order of magnitude of between D / 30 and D / 7 and in particular between 0.5 and 2 mm lie. And finally, the rib pitch T, which is the axial width of an inner one Rib base 2, 12 plus the axial width of a rib flank 4, 14 plus the axial width of a rib apex area 3, 13 plus another Rib flank 4, 14, between D / 3 and 2 x D and in particular between 5 and 15 mm tall.

The two rib shapes shown in FIG. 1 differ in that that the ribbing shown in the upper half of the ribs 4 with straight lines Show course, while the ribs 14 of the lower half of the image are sinusoidal are curved, the turning point of the slope of the flanks 14 den defines the maximum angle of inclination β, which must be greater than 45 °. The pitch angle In contrast, the upper rib is over the entire flank length equal.

It should also be mentioned that a smaller pitch angle α or β due to the smaller support surface on the concrete with tensile loads per se less shear the ribs creates an obtuse angle greater than 45 ° because the ribs with axial tensile loads not only push the concrete outwards like a wedge, but at the same time pressed radially inwards by the concrete.

On the other hand, there are obtuse angles of incline, the rib flanks of which are better suited Support concrete and the resulting axial force components are larger than the inward radial force components for such flanks with an obtuse angle of inclination, more likely to shear off than the one with a sharp one Incline. In this respect, it is for the present invention with an obtuse pitch angle all the more important that the ribs have a wide rib base and therefore have a good bond with the reinforcement bar underneath. First then you can do both tasks with one and the same design, namely on the one hand the shearing off of the ribs and on the other hand a split tensile failure prevent.

In summary, the present invention offers the advantage that it is stable for the first time fiber-reinforced plastic reinforcement bars can be proposed their ribs neither shear off under the usual tensile loads, nor due to the obtuse pitch angle to the effect of the so-called split tensile failure to lead.

Claims (10)

Reinforcement bar (1), made of fiber-reinforced plastic, provided on its circumferential surface with a radially outwardly projecting profile in the form of ribs which extend at least over part of the circumference,
characterized in that the lateral rib flanks (4, 14) forming the transition area between the inside rib base (2, 12) with diameter d and the outside rib apex area (3, 13) with diameter D have an incline at least in some areas with an angle (α, β) of more than 45 ° with respect to the rod axis (5), and that the axial width A of the rib regions with at least half the rib height H / 2 = ½ x (Dd) / 2 is greater than the axial distance B between the at least half the rib height Rib areas of two adjacent ribs. Reinforcing bar according to claim 1,
characterized in that the axial width of the rib base R formed by a rib (3, 13) including the two laterally adjacent rib flanks (4, 14) is greater than the axial width of the rib base (2, 12) including the two laterally without ribs adjacent concrete flanks (4, 14) formed concrete bracket base B. Reinforcement bar according to at least one of the preceding claims,
characterized in that the ribs form a radial distance, forming the rib height H = (Dd) / 2, between the rib base (2, 12) with diameter d and the rib apex region (3, 13) with diameter D in the order of magnitude of between D / 30 and D / 7 have. Reinforcement bar according to at least one of the preceding claims,
characterized in that the rib pitch T, that is the sum of the axial width of the rib base R formed by a rib (3, 13) including the two laterally adjacent rib flanks (4, 14) and the axial width of the adjacent non-ribbed rib base (2, 12 ) is on the order of between D / 3 and 2 x D. Reinforcement bar according to at least one of the preceding claims,
characterized in that the plastic of the reinforcing bar (1) is reinforced with glass fibers and / or carbon fibers. Reinforcement bar according to at least one of the preceding claims,
characterized in that the ribs (3, 13) run helically around the circumference of the rod. Reinforcement bar according to at least one of the preceding claims,
characterized in that the ribs (3, 13) are inclined to the rod axis (5) and deviate from the perpendicular to the rod axis. Reinforcement bar according to at least one of the preceding claims,
characterized in that the reinforcing fibers are also shifted into the ribs (3, 13). Reinforcement bar according to at least one of the preceding claims,
characterized in that the profiling of the reinforcing bar is formed by introducing radial depressions, the ribs and the radially outer rib apex regions being formed by the rod jacket surface and the radial depressions each forming the radially inner rib base. Reinforcing bar according to claim 9,
characterized in that the radial depressions are introduced locally and in particular distributed over the circumference of the reinforcing bar.

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