DE10159966A1 - System for measurement of the bending strength of a mast, especially a mast made of brittle material, in which a number of partial loads are applied to the mast at different heights, thus preventing damage during testing - Google Patents

Abstract

System for testing the bending strength of the foot (2) of a mast (1) that is anchored in the ground (3), where said mast is manufactured from a relatively brittle material such as concrete. To measure the bending strength at least two partial bending loads (P1-P3) are applied at different heights up the mast. The applied load is approximately equal to the minimum testing load and the partial loads vary proportionally with mast diameter. An Independent claim is included for a method for bending mast bending strength.

Description

The invention relates to a system for testing the bending strength of a mast foot standing mast anchored in the ground, preferably made of concrete or the same relative to steel tube brittle material, with means for applying the Masts with a bending moment and with means for detecting a bending moment corresponding deflection of the mast. It also relates to a procedure for Testing the bending strength of a standing mast anchored to the base of the mast, especially for use with masts made of a relative to steel relative brittle material, such as concrete, by exerting a bending moment on the mast and Detection of the mast deflection caused by the bending moment. The Flexural strength of a mast generally includes within the scope of the invention mechanical stability of the mast and normally also its stability in the Soil, i.e. the stability of the mast foundation.

The masts of the type to be checked include carriers of traffic signs, Traffic lights, lights, overhead lines and the like. An important area of application for Invention are the relatively tall lamp poles on streets or squares. Through the Testing the bending strength should be found out at those masts who are at risk of being caught in a storm or even light Bend the maneuvering contacts with a motor vehicle. This is done with the usual Test methods aimed to simulate the suspected impact of a storm. Most of time For this purpose, a pressure against the (unclamped) free mast top (Bending) force exerted and thereby the free upper part of the in or on the floor anchored mast bent away from the position of the acting force unit. The at The respective bending test applied to the mast should according to the current standard to be about 1.5 times the theoretical wind load to make sure that the tested mast - at least until the next test - everyone Withstands storm. These minimum forces to be exerted during the test are also referred to as the minimum test load.

A system of the type mentioned is described in DE 195 40 319 C1. in the Known is a device for testing the bending strength of a standing in Floor-anchored metal mast described. The mast is attached to a single one Place a bending moment at a distance above the floor. The result caused mast deflection is also by means of a distance above of the floor arranged displacement sensor detected. To prevent the mast base due to the bending load introduced into the mast to exert the bending moment The well-known system provides for the medium to be shifted excessively horizontally to apply the bending load via a flexible connecting means on the mast base anchor. If there are still smaller horizontal displacements of the mast base when applying the bending load appear possible, the mast foot is immediate an additional displacement sensor on the floor for detecting the position of this mast part assigned.

Another system of the type mentioned with at least two measuring points is described in DE 100 08 202 A1. In this case, the Measurement results from different height positions of the mast on one To combine light receivers directly comparable.

The known measuring methods are mainly on masts made of metal pipe, for. B. from Steel, aluminum or a similar elastic material. It can be assumed that the material of the mast is so pressure-resistant that it is in the Generally, bending load introduced almost selectively into the mast without damage receives. However, there are masts made of concrete or one in comparison to tubular steel similarly brittle material, which due to the pressure load during the Mast testing procedure, e.g. B. sustainably damaged by flaking of concrete parts can be. It is often difficult to determine objectively whether the mast is already in front of the The test was damaged or only became damaged by the test.

The invention is based, so the mast test described the task to develop masts made of concrete or similar brittle material are to be checked without the specified increased risk of material damage is to be accepted by the examination itself.

The solution according to the invention for the system of the type mentioned at the outset is that the mast has at least two different altitudes a partial Bending load is assigned. Preferably, the sum of the in the mast initiated bending loads are approximately equal to a minimum test load. For the The above-mentioned method, the solution according to the invention is that Bending moment caused by at least two spaced one above the other Positions on the mast are caused by partial bending loads. Some Improvements and further refinements of the invention are described in the Subclaims specified.

The invention ensures that the total in a - z. B. cylindrical, conical or stepped mast - minimum test load to be introduced on two or more positions (spaced along the mast) must be distributed. This will the one to be applied to the individual position - essentially selectively Test pressure is reduced accordingly and it becomes possible to load the minimum test load in distribute individual "portions" along the length of the mast. The point load - briefly "partial pressure" - is reduced and at the same time is the assumed one Simulate wind loads better than before. The at the individual debit point in partial pressure introduced by the mast can be selected by selecting the number of inlet points for the bending load is reduced so that a pressure sensitive material, like concrete, existing mast, if it is still in order, through which Test itself is not damaged.

Surprisingly, the invention makes it possible to choose the one described Partial prints also differences in stability, in particular Differences in diameter to be taken into account along a mast. For example, with a mast whose Diameter in its longitudinal direction, e.g. B. tapered or gradually, varies Another inventive idea, the size of the (partial) bending load on their Attack positions along the mast in the same direction as the mast stability vary. According to this, the partial bending load can preferably be proportional to Mast diameter or for mast stability (along the mast) to be changed. That applies both with a mast that is conical in its longitudinal direction and with a mast, whose diameter gradually decreases from bottom to top. Regarding the Wind simulation is taken into account here that the small mast diameter Offer less resistance to wind than larger areas Diameter. The invention can also other stability standards, for. B. the mast Wall thickness, take into account.

The application of the invention is particularly useful in the event that the mast has an inspection door. The mast stability is in the area of the inspection door naturally weakened. To take this weakening into account, see Another inventive idea, at least one partial bending load with a distance above the inspection door and another partial bending load below the inspection door in to initiate the mast. It may be advantageous to use the lower partial bending load larger than the one introduced into the mast above the inspection door Select bending load to account for the weakening through the inspection door wear. Of course, two or more can also be located below the inspection door individual bending loads are exerted on the mast.

According to yet another invention, there is the means for loading the mast with the respective bending load from a load extending along the mast Beam which should be placed on the mast at two points one above the other and with the help of a single power source with the two points at the same time against the Mast to be pressed. In this way, the required minimum test load can be obtained with the help a single power source on two mast positions spaced one above the other become. The partial bending loads introduced into the mast can be the same be when the (only) power source attacks in the middle of the beam. But when the bar is designed as a double lever with an off-center force source , it is possible to apply the partial bending loads to the two attack positions of the To design bars in any dimensions differently, so that the aforementioned Advantages with two different partial bending loads, even with a single one Power source can be reached using the bar.

In concept, the invention is primarily for use with brittle masts Material such as concrete. The load distribution according to the invention on the length the mast can also be flexible and selective with masts Do not damage pressure-resistant material and under certain circumstances, e.g. B. in the field of Revision door weakened mast stability, even be unexpectedly beneficial. The Mast weakening in the door area can be due to the shape or Size as well as the position of the door (deviating from the norm spatially too deep). at some mast materials, e.g. B. with aluminum, excessive weakening of the Door area also due to previous, strong mast vibrations which the material structure has been changed. In the sense of the Invention also exist these weakened mast areas - even with metal masts - made of a material which is "brittle" relative to (un weakened) steel pipe.

Based on the schematic representation of exemplary embodiments Details of the invention explained. Show it

Fig. 1 shows a standing mast, to act at a distance of three partial bending loads from one another; and

Fig. 2 act a standing mast on the two partial bending loads at a distance from each other starting from a single load beam.

In Fig. 1 and 2, a concrete pole is shown 1, which is anchored at its mast foot 2 in the soil. 3 The mast 1 can have an inspection door 4 . In the exemplary embodiment it is assumed that the mast diameter decreases linearly starting from the bottom 3 , that is to say the mast is conically shaped. In Fig. 1, an alternative with a step-like profile of the mast diameter is also shown in dashed lines. There are masts with one, two or more of the diameter steps 5 shown in dashed lines.

According to Fig. 1 it is provided that three partial loads P1, P2 and P3 act on the mast 1 . The partial loads P1, P2 and P3 can in principle be the same, but they can also be selected to be of different sizes, as symbolized in FIG. 1 by the arrow length. If the mast cross-section decreases linearly from bottom to top in the longitudinal direction 6 of the mast, the partial bending loads P1 to P3 can decrease in the same ratio as the diameters at the positions 7 to 9 in the direction 6 from one to the next partial bending load. The partial bending load P1 attacking at position 7 is then greater than the bending load 2 attacking at position 8 and this in turn is greater than the partial bending load P3 attacking at position 9 . The proportionality of the bending loads P1 to P3 can in principle also be left with the mast diameter decreasing linearly in the longitudinal direction of the mast; this can be particularly advantageous if a revision door 4 is provided in the mast 1 between two load positions 7 and 8 .

Fig. 2 shows an arrangement with a mast 1 and a load bar 10 placed on the other hand with the aid of a total bending load (e.g. minimum test load) P, which with two load feet 11 and 12 , e.g. B. below and above at load positions 7 and 9 , on the mast 1 and is pressed by the effect of the total bending load P against the mast 1 . If the total bending load P acts on the load beam 10 in the middle of the beam length, that is to say in the beam center 13 , it can be assumed that the partial forces exerted on the mast 1 at positions 7 and 9 are approximately the same. However, if the total bending load P - as shown in FIG. 2 - is exerted on an eccentric point of application 14 of the beam 10 , the partial bending loads introduced into the mast 1 at positions 7 and 9 behave like the drawn-in leg lengths b to a of the load beam 10th The load beam 10 can then be seen as a kind of double lever with the lever arms a and b. The load beam 10 can of course be combined with further partial bending loads; if necessary, the total bending load acting on the load beam 10 is only part of the minimum test load.

The mast deflection caused by the partial bending loads P1 to P3 can be measured in any manner using the invention. For this purpose, two measuring devices 15 and 16 are symbolized in the drawing at a distance above the floor 3 or close to the floor 3 . LIST OF REFERENCES 1 Mast
2 mast feet
3 floor
4 inspection door
5 level
6 mast longitudinal direction
7-9 load positions
10 load bars
11 , 12 load foot
13 middle of bar
14 point of attack
P total bending load
P1-P3 partial bending load
15 , 16 measuring device

Claims (8)

1. System for checking the bending strength of a standing mast ( 1 ) anchored to the mast base ( 2 ) in the floor ( 3 ), preferably made of concrete or the like brittle material relative to tubular steel, with means for applying a bending moment to the mast and with means for Detection of a deflection of the mast corresponding to the bending moment, characterized in that the mast ( 1 ) is assigned a partial bending load (P1, P2, P3) in at least two different heights ( 7 to 9 ). 2. Installation according to claim 1, characterized in that the sum of the partial bending loads (P1, P2, P3) introduced into the mast ( 1 ) is approximately equal to a minimum test load (P). 3. Plant according to claim 1 or 2, characterized in that a partial bending load (P1) engages at a distance below a revision door ( 4 ) of the mast and a partial bending load (P2) above the revision door on the mast. 4. Plant according to at least one of claims 1 to 3, characterized in that the means for loading the mast ( 1 ) with the partial bending loads (P1, P2) consists of a load bar ( 10 ) extending along the mast, which on Place two points ( 7 , 9 ) at a distance from each other on the mast and, with the help of a single power source (P), at the two points at the same time move against the mast. 5. Plant according to claim 4, characterized in that the load beam ( 10 ) is designed as a double lever with off-center attacking power source (P). 6. Plant according to at least one of claims 1 to 5, in a mast, the stability, in particular diameter and / or wall thickness in its longitudinal direction ( 6 ), for. B. varies conically and / or gradually, characterized in that the size of the partial bending load (P1 to P3) at their attack positions ( 7 to 9 ) along the mast ( 1 ) varies in the same direction as the mast stability. 7. Plant according to claim 6, characterized in that the partial Bending load varies in proportion to the mast diameter. 8. A method for testing the bending strength of a standing mast ( 1 ) anchored to the mast base ( 2 ) in the floor ( 3 ), in particular for use with a mast made of a material which is relatively brittle compared to steel pipe, such as concrete, by exerting a bending moment the mast and detecting the deflection of the mast caused by the bending moment, in particular for operating the system according to at least one of claims 1 to 7, characterized in that the bending moment on the mast by at least two positions ( 7 to 9 ) one above the other ( 1 ) applied partial bending loads (P1, P2, P3).