NL7904427A - Reinforced concrete rod prestressing system - using lubricant while stretching bars in structure to desired amount - Google Patents

Abstract

The dynamic pre-stressing system stretches one or more bars in a pre-stressing structure to the desired amount. The stress can be alternately increased and reduced, so as to make it steadily greater. A lubricant can be used whose lubricating action increases with vibration, e.g. consisting of grains and liquid, so that when vibrated excess tension is generated in the liquid with consequent reduction in grain friction. Amplitude and frequency can be such as to generate a lengthwise wave giving a progressive effect on movement of the bar.

Description

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Priority invoked: 11/1/79 No 7900219 22/2/79 No 7901395 DYNAMIC PRELIMINARY.

The present invention relates to a method of tensioning the reinforcement of a prestressed structure. In this method, the tension or tension is applied during the tensioning. elongation of the biasing material is not progressively applied in a straight or curved line (quasi static, see fig. 1) but dynamically increasing, i.e. applied in a pulsating or * modulating manner (see fig. 2).

In the current state of the art, the prestressing reinforcement is predominantly tensioned with hydraulic jacks. The tensile force in the reinforcement is gradually increased, with or without a break for the purpose of relaxation. It is a known phenomenon that the tension in the longitudinal reinforcement does not remain the same. Due to namely, the biasing will lengthen and displace the rod in the pre-tensioning construction. The displacement of the rod relative to the surrounding prestressed structure creates friction between the rod and the structure. Due to this friction, the prestressing force in the bar decreases as the distance from the prestressing screw increases. This structure is even larger with curved rods due to a radial component% bending force which acts between the prestressing rod and the structure. This voltage drop means a decrease in the prestressing force and often less economical use of the prestressing reinforcement and / or a less 790442? -I * s' · * i,.

- 2 -ή favorable load on the construction.

The aim of the present invention is to overcome or reduce this drawback by reducing the friction between the biasing rod and the structure.

In the present invention, the rod is vibrated during tensioning. The purpose of this vibration is to keep the rod moving more continuously and faster, if possible, with a direction of movement which varies according to the construction. It is a known fact: that a faster and especially vibrating movement will reduce friction. The invention also includes a method in which a sliding material is used which is sensitive to a vibrating movement and whereby a greater lubricating effect is achieved. (See fig. 3) The invention also includes the use of a vibration whose amplitude and frequency -quickness is adapted to the overall system such that a longitudinal wave is created in the reinforcement which has the effect (streaking) that the reinforcing bar creeps in the desired direction (see fig. 4). Also included in the invention is a profiling of the prestressing steel such that the vibration also has a moving (poaching) effect comparable to the creeping effect of an ear of corn (see Fig. 5). The invention also includes the use of a multi-bar prestressing reinforcement which is composed in such a way that the vibration creates a transverse contract and dilatation which has a favorable effect on reducing the friction (see Fig. 6). Finally, the invention also includes a method in which the duct tube or the hole-wall in the construction through which the reinforcing bar is applied has such a special design that it also has a favorable effect on reducing the friction due to the vibration applied. (see fig. 7). Dynamic pre-tensioning can be carried out in a simple manner 7904427 • i Λ * _: Vi -: 3 - .. ’ή by using a hydraulic clamping screw in which a hydraulic alternating or impulse flow is applied instead of a quasi static oil flow. Insofar as this method can fall under "modulating pressing" for which patent 5 no. 7900219 is pending, a right of priority is invoked, a right of priority is also invoked insofar as applicable for the patent application "universal alternating current generator" no. 7901395 Since the prestressing reinforcement has a relatively large elongation below-10 at the usual prestressing length and in order to prevent damage to the construction, in most cases it will only be possible to have limited variations. on the rack. In that case we speak of modulating prestressing {see fig. 2). The effect of the friction reduction will be increased and the movement of the rod relative to the construction will be improved when such a longitudinal wave is generated in the rod that it gives a "creeping" effect (see Fig. 4).

Another, in some cases even simpler, method consists in placing an element which has a dynamically changing length during tightening (see fig. 8) between the clamping screw and the construction on which the reaction force of the screw engages. Due to the quasi-static drive with clamping screw, the average elongation of the bar will always increase, while due to the dynamic length change of the member this total length change occurs in a modulating or pulsating manner. This member can consist of one or more hydraulic cylinders driven by an alternating hydraulic current or by a hollow hydraulic cylinder (see fig. 9). Another possibility to make the member vibrate in length is to use another conventional vibratory drive such as a vibrator motor (see fig. 10) 7904427

Claims (14)

2. Dynamic prestressing in accordance with concl. 1 characterized in that the stretching of the prestressing bars is effected dynamically. 3. Dynamic prestressing according to concl. 1 and 2, characterized in that the rack or. tension alternately increases and decreases again, but such that in total the average elongation or. voltage keeps increasing (see fig. 2). 4. Dynamic prestressing according to previous claim. characterized in that a lubricant is used which has a higher lubricity under vibration. E.g. a lubricant built up of granules and a liquid the gradation of which is such that as a result of the vibration an overvoltage in the liquid is created, resulting in a smaller internal grain friction (see fig. 3). 5. Dynamic prestressing according to the previous claim. characterized in that the amplitude and frequency is arranged in such a way that a mono-rududinal wave is created which effects a progressive effect. ^ on the displacement A / bar (see fig. 4). ! ^ 6. Dynamic prestressing according to the preceding claim, characterized in that the prestressing bars are such. profiled that the vibration, in addition to reducing the friction, has a progressive effect on the bar similar to the "creep" of an ear of corn (see fig.5). 1 ï 7. Dynamic prestressing according to previous claim. characterized in that when using composite prestressing bars the {composition of the bars is such that due to the dyna-. , "$ N" dilatation bias a transverse contraction course in the combined bars, which improves the effect of the characteristics 7994427 j 4 m 1 * · ίί '___ - "5" _ 1 to "" (see fig. 6 / γ - / ____ '. / ^ / -. 8. Dynamic, prestressing According to the previous claim. characterized in that the construction of the ductube. whether the hole wall in the construction is chosen such that the effect of the friction reduction and / or the advancing effect according to claim 1. 5,6 and 7 is improved, (see fig. 7) 9. Dynamic prestressing in accordance with the previous claim! characterized in that the bias material is of a technological quality such that relaxation is accelerated when dynamic bias is used. j r 10. Dynamic prestressing according to previous claim :. characterized by e.g. stretching and prestressing of the prestressing reinforcement one or more hydraulic tensioning jacks are used. ; i 15. 11. Dynamic pre-tensioning according to the previous claim !. characterized in that the bias self) are driven by a hydraulic alternating or impulse current instead of a quasi static current. 12. Dynamic prestressing according to previous claim. characterized in that the hydraulic alternating or impulse flow is arranged in such a way that the above-mentioned concl. described effects of frictional reduction of longitudinal waves. . and of advancing creep effects and that, where applicable, priority is claimed of the 25 patent applications dated. 11/1/79 and 22/2/79 with the numbers - resp. 7900219 and 7901395. 13. Dynamic prestressing according to previous claim. characterized in that the dynamically varying voltage or. stretching in the prestressing reinforcement can also be achieved by arranging a special member between the tensioning auger and the construction to which the reaction force of the tensioning auger connects. Dynamic prestressing according to claim-13, characterized in that 7104427 / & / '' -6- 'changes the length of the member such that on the rack exerted by the clamping screw. tension a vibrating stretch or. tension is superimposed. (see fig. 8) 15. Dynamic prestressing according to concl. 13 and 14 characterized in that the member is composed of a multiple polymer vybrocylers or a hollow vybrocylinder driven with an alternating hydraulic current such that the effects contemplated in the preceding claim. be reached, (see fig. 9) 16. Dynamic prestressing according to part of the previous 10 concl. characterized in that the dynamic change in length of the above-mentioned member is generated by another vibrating drive such as a vibrating motor, electric vibrating generator or the like (see fig. 10) - With the abbreviation concl. is meant conclusions. - Reference in figures according to subnumber: .1 clamping screw? .2 "organ"; .3 construction; .4 prestressing reinforcement? .5 hollow cylinder? .6 hybrid cylinder; .7 vibration motor 7 .8 eccentric. 7904427 ^ -