NZ227820A - Threading reinforcing rounds - Google Patents

Description

22 7 8 2 0 Priority D3U^s):...;..A3.

Comp<!>»? Specification Flted: Class: (G v> .

Publication Date: P.Qu Journal, No: r i? i Patents Form No. 5 NEW ZEALAND PATENTS ACT 1953 COMPLETE SPECIFICATION E/~~ MECHANICALLY JOINIJ REINFORCING ROUNDS V * ;MECHANICALLY JOINING CONCRETE^/ °*V - 1 F£BI9S9 m i ^/We, TECHNIPORT S.A., A French Company, of 276 Avenue de la Marne, 59700 Marcq-En-Baroeul / FRANCE hereby declare the invention, for which j^we pray that a patent may be granted to rii^/us, and the method by which it is to be performed, to be particularly described in and by the following statement: (followed by page la) - la- 2 7 8 2 0 " 1 The invention relates to a method for mechanically joining concrete-reinforcing rounds, to a reinforcing round allowing the application of said method as well as to a mechanical joint of reinforcing rounds thus produced. The invention is applicable in particular in the construction of concrete building components or concrete structures.

Currently, such reinforcing rounds are connected by way of joints having the function of transmitting the tensile stress; in addition, the joint must be easy to set in place and be of a low cost. Various solutions have been proposed by constructors to bring about the mechanical joining of reinforcing rounds.

There exists first of all the overlap joint system. This method has several drawbacks. In particular, it is necessary to leave pending a relatively big length of the reinforcing round, up to two metres, for example, in order to subsequently produce the joint, which is troublesome and difficult and often even impossible to fold back by reason of the large diameters encountered.

Another proposed method consists in utilizing a mechanical joint. There is known for example the system of conical threading in which the extremities of the rounds to be joined are machined to have the shape of a conical thread, by means of which they can be inserted and screwed into a connector to be embedded in a block of concrete.

This solution suffers from numerous drawbacks. In particular, the conical threading is effected on a solid bar at the nominal diameter of the reinforcing round. The machining of the thread diminishes locally the cross-section of the bar which then corresponds substantially to the cross-section at the bottom of the thread.

During tensile tests, the rupture of the reinforcing round always occurs at its extremity in the threaded zone. Consequently, it cannot be doubted that this method of mechanical jointing weakens the reinforcing round, which must be overdimensioned accordingly to take into account the local weakness in the threaded region. (followed by p-^qe 2) ^2 7 8 2 0 Nor does this system allow the use of a simple connecting sleeve with right-hamd and left-hand thread to constitute the joint with adjustmet of tension. It is necessary to employ several parts to constitute a stack and allow for adjustment of length.

Lastly, the tightening of the sleeve on the conical thread must be effected with a preset torque, which has to be monitored. This operantion is not easy to perform on a construction site, but it is nevertheless indispensable for safety reasons. If the tightening torque is not achieved, there are risks of dislocation and a total absence of resistance to traction.

From the economic point of view, this is an expensive solution, because the machining of the sleeve is a complex operation and, in particular, the thread must be cut in two stages.

In conclusion, this technique necessitates an overdimensioning of the diameters of the reinforcing rounds of the order of 20 %, in order to withstand the stresses which concentrate at the threaded extremities of the bars. Its costs are high.

Another mechanical joint has also been already used. This consists in a crimping of the extremities of the reinforcing rounds to be joined. To this end, there is employed a socket into which are inserted the two extremities of the reinforcing rounds. The socket is then crimped on the rounds with the aid of a jack and a press.

This technique is fraught with high risks of slippage owing to the crimping which is far from easy to achieve and difficult to control. This defect considerably reduces the mechanical strength of the joint. On a construction site, it is often difficult to position a press level with the socket to be crimped.

Also, the use of a press is costly.

Further, with regard to the regulations governing the use of such mechanical joints of reinforcing rounds it is of course prescribed that the latter must be able to withstand ultimate rupture stress and certain Countries, especially the Anglo-Saxon Countries, impose very rigorous slippage-control standards. 22 7 8 In Great Britain, for example, the Standard BS-81 10 : part 1; 19 85-3.12.8.16.2 specifies that reinforcing rounds assembled by means of a connecting sleeve must be able to withstand a tensile test in which the rounds are subjected to a stress corresponding to 60 % of the elastic limit, following which the permanent elongation may not exceed 0.1 mm.

These standards are even more rigorous in some other countries. For example, in the United States, the stress applied corresponds to 80 % of the elastic limit. Similar tests are also applied in the nuclear industry.

These tests, when carried out on a site, are difficult to put into effect, requiring the use on the site of torque wrenches which increases the cost of the finished joint.

Moreover, if the machining of the different components has not been carried out with precision, it may happen that during the subsequent testing the mechanical joint does not satisfy these standard specifications. It is then necessary to start all over again, which is not without infuence on production costs. On the other hand, precision fabrication requires a highly skilled workforce and special attention to detail of such an order that the solution ceases to be an economically viable one.

The principal object of the present invention is to provide a method for effecting the mechanical jointing of reinforcing rounds, a reinforcing round allowing the application of said method as well as a mechanical joint of reinforcing rounds thus produced which offer the advantages of a high degree of safety in use, ease of application and competitive cost, whilst remedying the disadvantages of the known systems.

In terms of the present invention, with regard to safety of usage, the tensile tests carried out have shown that the rupture always occurs in the solid bar and to in the zones of the mechanical joints any more, as has been traditionally the case. Accordingly, the mechanical joint of the present invention does not constitute a zone of weakness.

Furthermore, the ease of application is achieved by means of a threaded connecting sleeve. This method allows in particular a positional adjustment of the rounds and the amount of tightening equipment is limited, which is particularly advantageous for on-site use. 22 7 8 In economic terms, the method of the present invention involves only a limited amount of machining and the utilization of conventional non-constraining means.

One object of the present invention is to propose a method for producing mechanical joints for reinforcing rounds, a reinforcing round allowing the application of said method and to a mechanical joint of reinforcing rounds thus produced, which allow to satisfy very rigorous deformation criteria imposed by certain standards or regulations, which specify testing up to 80 % of the elastic limit.

Another object of the present invention is to propose a method for producing mechanical joints for reinforcing rounds which allows to provide mechanical joints in which all the threaded rounds are tested, which is of fundamental importance in terms of quality control and which provides for an important structural guarantee.

Whilst hitherto the known techniques did allow to produce mechanical joints, only those parts could be considered reliable which have been tested. The present invention constitutes an important step towards a 100 % reliability, due to the fact that all the rounds are tested.

Other objects and advantages of the present invention shall be exposed in the following description which, however, is given only by way of an example and which is not intended to limit the invention in any way According to the invention, the method for producing mechanical joints of reinforcing rounds, which is applicable particularly in the construction of concrete elements or structures, by means of which reinforcing rounds can be joined the extremities of which are threaded by means of tapped connecting sleeves, is characterised in that prior to the threading of the extremity or extremities of the reinforcing rounds to be joined are treated by cold upsetting.

The reinforcing round, allowing the application of the method according to the invention, is characterised in that it has at least one threaded upset extremity. 227820 The mechanical joint of the reinforcing round, produced by the application of the method according to the invention, in which two reinforcing rounds are joined substantially coaxially by the intermediary of a threaded connecting sleeve, is characterised in that the extermity or extremities of the rounds to be joined have a thickening in the zone of the threaded portion for reinforcing purposes.

The invention will be better understood from the following description made with reference to the accompanying drawings, in which: Figure 1 diagrammatically illustrates the joint of two reinforcing rounds according to one mode of application of the present invention, Figure 2 illustrates the mechanical joint of fixed reinforcing rounds, Figure 3 illustrates a third example of mechanical joint of reinforcing rounds in the zone of an anchoring point, Figure 4 shows diagrammatically a prestressing device for the reinforcing rounds according to the present invention, Figure 5 is a diagrammatic illustration of a variant of embodiment of the prestressing device shown in Figure 4.

The present invention has for object a method for embodying the mechanical joint of reinforcing rounds, a reinforcing round allowing the application of the said method, as well as a mechanical joint of reinforcing rounds thus conformed which will find applications especially in the construction of concrete elements, buildings or structures.

In this field of activity, there are employed tension pieces which pass through the concrete elements completely and which are tensioned to generate a compressive stress in the concrete. The adjustment of the tensile stress and the choice of location of the tension pieces must be carefully determined by calculation In practice, the tension pieces are formed by an assembly of reinforcing rounds placed end to end. The joint employed to integrate the reinforcing rounds Z2 7 8 must be capable of absorbing the tensile stress, must be easy to set in place whilst being also economical to produce.

Currently, various solutions are being proposed, such as overlap joints or crimped joints, but these involve high-cost requirements in their application and have numerous disadvantages.

The mechanical joint according to the present invention allows to effect the substantially coaxial, end to end assembly of two reinforcing rounds 1 and 2, as illustrated in Figure 1. A threaded connecting sleeve 3 is utilized to receive the threaded extremities 4 and 5, respectively, of the reinforcing rounds 1 and 2.

With regard to the threading and tapping, two solutions may be considered, namely: the use of the extremities of the bars having the same right-hand or left-hand thread, in which case it is necessary to achieve a tightening by rotation of the bar 1 or 2; alternatively the use of the threaded extremities 4 and 5 having inverse right-hand and left-hand threads and the same for the appropriately tapped sleeve 3, in which case the tightening is achieved by rotation of the connecting sleeve 3. In this regard, the application of the present invention has no restrictions.

However, if a simple thread is produced at the extremity of the reinforcing rounds 1 and 2, tensile tests show chat the ruptureof the bars always occurs in the threaded zone of one of the bars. This phenomenon can be explained by the fact that the cross-section of the bar is reduced at this location. In fact, the threading produced on the surface of a reinforcing round cuts into the section and, as the latter becomes smaller, a weakening results.

With the mechanical joint of the present invention, a reinforcement of the extremity of the reinforcing round is produced, in such a manner, that the latter is stronger than the central portion of the bar.

Thus, under tensile load, the rupture occurs in the central portion of the bar and not at the level of the joint any more. The choice of the section of the reinforcing round can be made as a function of the required strength to be obtained in the central part of the bar and-not in the weakened portion of the joint as is conventionally the case. At equal mechanical strength, the reinforcing rounds employed within the scope of the present invention will have a smaller cross-section, which allows to achieve a substantial economy. 22 7 8 2 0 According to the principal feature of the present invention, the reinforcement of the extremity of the reinforcing round to be joined is achieved, prior to threading, in a cold-upsetting operation.

It is appropriate here to insist on the distinctive character of the operation contrary to the practices customary in this field. The conventional cold-upsetting technique aims at obtaining dimensional modifications of the machined part in excess of 30 %. For example, a diameter of 40 mm, after cold-upsetting by the conventional methods, results in a diameter of the order of 55 mm. However, such a deformation of the material does not bring about the expected results and leads to a loss of mechanical strength. This loss is essentially localised within the zone of diameter change. Tensile tests show that the rupture occurs in this region.

According to the invention, the extremity is reinforced over the threaded length in a cold-upsetting operation, which brings about an increase in diameter equal to or less than 30 %, in particular comprised between 10 and 30 %.

This value allows to achieve both an increase in mechanical strength due to increase of cross-section and also a small increase of internal stress so as not to weaken the reinforcing round in the zone of diameter change.

The Table 1 indicates, by way of example, the values of diameter d^ of the upsetting to be achieved prior to threading as a function of the nominal diameter $ of the bar used, giving good practical results .

TABLE 1 p nominal mm d<1 thread mm ~ <P $ 16 % 24 % % 32 36 12 % 40 45 12 % 50 56 12 % 56 64 14 % The tabulated values show that in terms of percentage the cold upsetting mav diminish as the diameter of the bar increases- The diameter of the reinforcing rounds at the bottom of the thread, of the upset extremity must be at least slightly "greater than the overall section <}> of the reinforcing round to be joined. '4 J O' 2 5 MAY 1992 y o '! ^2 7 8 2 0 The upsetting operation according to the present invention is to be preferably carried out cold. Actually, a hot upsetting has the drawback of weakening the transition zone by reason of the uncontrolled cooling. In general there results an over-tempering which weakens the metal. Moreover, the hot process has to be applied outside the construction site because it requires furnaces which have to be supplied with power often not available on the site.

Given that the concrete-reinforcing rods are generally produced in steels with high carbon and manganese content, they are very sensitive to thermal shocks so that cold-upsetting is preferred.

The length of the threading produced at the extremity of the concrete-reinforcing rods should substantially correspond to the diameter o the said rod in order to achieve a safety margin, given that threaded lengths of 0.7 times the diameter are sufficient to resist tension. However, this length may be greater.

The mechanical joint according to the present invention could also be applied in the case of fixed reinforcing rods, which cannot be pulled apart, as illustrated in Figure 2. In this case, one of the bars 1 has a threading 4 of double length produced about an upset extremity, and the sleeve 3 initially placed around the thread 4 will be displaced by rotation to cover the threaded portion of the reinforcing rods 2. The threads 4 and 5 will have the same pitch.

It is also necessary that the application of the mechanical joint according to the present invention may equally be established at the anchoring points of the profiles 1, as is illustrated in Figure 3. In this case, the threaded extremity 4 of the reinforcing rod should be previously treated by cold-upsetting in order to reinforce it, and this extremity is fixed in an anchoring socket 6 integral with the concrete block 7.

Moreover, in order to withstand the tensile tests imposed by certain safety standards, the extremity 4 and/or 5, reinforced by upsetting, is prestressed.

This prestressing allows to cancel out all the displacements and elongations of the concrete-reinforcing rods and especially those of their extremities in the safety tests applied. -2 7 8 2 In addition, due to this prestressing, it will not be necessary to employ torque wrenches on the construction site or to produce the threads with a high mechanical precision.

Thus, in order to realize the mechanical joints of the concrete-reinforcing rounds according to the present invention, the following procedure is to be adopted: prior to threading, the extremity or the extremities 4, 5 of the concrete-reinforcing rounds 1, 2 to be joined are subjected to cold upsetting; following this, the threading of the upset extremity or extremities 4, 5 is carried out by the conventional methods; lastly, the upset threaded extermity or extremities 4, 5 of the concrete-reinforcing rounds are pre-stressed prior to the mounting of the joint on the site.

To carry out this prestressing, Figures 4 and 5 illustrate by way of example two devices which may be used for this purpose.

In order to prestress the upset threaded extremity 4 of a round 1, for example, there is disposed thereon a threaded support sleeve 11, wherafter the round thus equipped is immobilised and the extremity 4 concerned is subjected to the action of a jack 6 or the like.

In the case shown in Figure 4, the extremity 4 of the round to be prestressed, fitted with its support sleeve 11, is inserted between a bearing plate 7 and the extremity 8 of the jack, When the jack 6 is actuated, the sleeve 11 is blocked against the bearing plate 7 and the jack acts directly on the extremity to be prestressed. Moreover, in order to mark the prestressed extremity, the end 8 of the jack may be fitted with a punch which produces an indelible mark in the region of the upset end 4.

Figure 5 illustrates a wholly equivalent but inverse procedure, in wich there is employed a threaded support sleeve 11 and a bearing plate 7. However, in this case, it is the body of the reinforcing round ^2 7 8 2 0 1 which is blocked, by some gripping device shown at 9 in the Figure, and the jact acts on the bearing plate 7 in the direction indicated by the arrows 10, which action is transmitted to the threaded support sleeve 11 to bring about the prestressing of extremity 4.

Depending on the specifications of the standards to be observed, there is effected a prestressing with an equivalent force comprised between 70 and 95% of the elastic limit of the concrete-reinforcing round.

Thus, this process of producing a reinforcing round allows to obtain a concrete-reinforcing round 1 or 2, having an upset, threaded and prestressed extremity 4 or 5.

It is obvious that other modes of execution of the present invention, within the reach of the Expert in the Art, could have been referred to without thereby exceeding the scope of the invention. 2k7 '62U

Claims (19)

WHAT WE CLAIM IS:

1. A method of forming a thread on an end of a concrete reinforcing round having a nominal diameter j§, suitable for use in the construction of concrete elements or structures in which threaded ends of reinforcing rounds are connected to threaded sleeves, comprising subjecting the end of the concrete reinforcing round to cold upsetting to produce a strengthened end portion whose diameter d^ is greater than the nominal diameter J and then forming a thread on the strengthened portion having a root diameter d£ between thread troughs equal to or greater than the nominal diameter If.

2. A method according to claim 1 wherein a thread is formed on each end of the concrete reinforcing round by the method of claim 1.

3. A method according to claim 1 or claim 2 wherein the or each end of the reinforcing round is cold upset for a length greater than the length of the thread to be formed thereon. ; J

4. A method according to any one of the preceding claims wherein the or each end of the reinforcing round is prestressed after a thread is formed thereon.

.. 5. A method as claimed in claim 4 wherein the ore-stressina Saw*' force is between 70% and 95% of the elastic limit of the reinforcing round.

6. A method as claimed in any one of the preceding claims wherein the diameter d^ of the or each upset end of the reinforcing round is up to 30% greater than the nominal diameter 3L. ^ 5:1 AY 1992 ~ - 13 -

7. A method as claimed in claim S wherein the diameter d^ of the or each upset end of the reinforcing round is at least 10% greater than the nominal diameter <j&.

8. A method according to any one of the preceding claims wherein the ratio (d^- (§)/<$ increases as the nominal diameter diminishes.

9. A reinforcing round formed by the method of any one of the preceding claims.

10. A concrete reinforcing round, suitable for use in the construction of concrete elements or structures in which threaded ends of reinforcing rounds are connected to threaded sleeves, having a nominal diameter and having a strengthened cold upset threaded end of diameter d^, greater than the nominal diameter (|>, and a root diameter d.2 between thread troughs equal to or greater than the nominal diameter jjT.

11. A concrete reinforcing round as claimed in claim 10 wherein the cold upset, threaded end is pre-stressed.

12. A concrete reinforcing round as claimed in claim 10 or 11 wherein the end of the concrete reinforcing round is prestressed for a length substantially equivalent to the nominal diameter J.

13. A mechanical joint comprising a concrete reinforcing round as claimed in claim 10 engaged with an internal thread of a connecting sleeve.

14. A mechanical joint for concrete reinforcing rounds as claimed in claim 13 including a further reinforcing round as claimed in claim 10 engaged with another end of thei SSi^^ially threaded sleeve. "V ;:7820 Hk -14-

15. A mechanical joint as claimed in claim 13 wherein the connecting sleeve is an anchoring socket.

16. A method of forming a thread on an end of a concrete reinforcing round substantially as hereinbefore described with reference to the accompanying drawings.

17. A method of forming a thread on the end of a concrete reinforcing round substantially as herein described with reference to any one of the examples.

18. A reinforcing round substantially is herein described with reference to the accompanying drawings.

19. A mechanical joint substantially is herein described with reference to the accompanying drawings. TE(2HNI]»0RT S.A. o