FI112816B - Rigid joint for connecting reinforcing piles with reinforced concrete - Google Patents

Abstract

The invention relates to a stiff joint for end to end jointing of precast concrete driven piles, each end of the precast concrete pile (P1, P2) of the joint comprising an end surface (10). The joining means comprise first planar joining loops (1) and second planar joining loops (2) forming a hole transverse to the longitudinal direction (Lp) of the piles and overlapping and located adjacent each other to form a joining space (9). The joining loop holes (3, 4) are mutually aligned (Lt) and a transverse locking pin (6) passes through them. Each joining space (9) comprises at least two first joining loops (1) at the end of the first pile (P1) and at least two second joining loops (2) at the end of the second pile (P2), and the joint comprises at least two such joining spaces disposed at a support distance from the central line (13) or bisectional plane of the pile.

Description

BACKGROUND OF THE INVENTION The invention relates to a rigid joint for the end-to-end connection of reinforced concrete struts, each of which is to be joined to the end of the main joint. forming at least one first planar connecting loop and at least one second planar connecting loop 10 extending longitudinally relative to each other in the joint and substantially adjacent to each other to form an interface at which the holes of these joint loops are aligned; and transverse locking pins passing through the overlapping connection loops.

Conventionally, reinforced concrete piles are connected end-to-end to provide the desired operating life of the punching pile. Generally, in a rigid joint, each end of the concrete pile entering the joint comprises a bottom plate corresponding to the pile cross-section in the end box to which the connecting members are welded. The connecting members typically consist of protruding locking spindles with a wide end and at least one abutment face facing the base plate and at least opposite locking housings provided with a cavity engaging the locking spindle and a transverse groove against the length of the locking spindles. between the abutment surface so that it stays in position by tying the pile sections together. There are numerous details of such joints, but some typical ones are described in FI-76169 and FI-77710. There are numerous drawbacks to these known pile joints. First, the construction of known joints is complicated and expensive to implement or uncertain in use. Secondly, both the lock body and the lock spindle must be manufactured by machining and with a high degree of accuracy, and secondly, in the constructions, the lock parts have to be welded to the base plate and / or to the steels, ie some be-30 tensile steels. Such a welding joint is unreliable in terms of strength, and in addition, due to thermal stresses, it is driven into a thick base plate. When such joints are broken when the pile is hit to the ground, it is the weld that is the most common cause of breakage. Thus, both material and labor costs are high. In addition, the lock housing 35 has an open recess in the open space, which easily accepts and stays in the water, which freezes when frozen, preventing the lock spindle from being pushed into place. Removing the ice before making the joint is laborious and time-consuming, which significantly slows down all piling. Further, such a base plate joint containing a locking socket and locking spindle often fails to straighten and rotate the base plate, which has been twisted due to either manufacturing or inadvertent processing, to the straight and perpendicular to the pile length, since direction and capture the force needed for the adjustment. This results in a high rejection rate because both the locking housings and the locking spindles must have a very small tolerance to the pile and the bottom plate must be very perpendicular to the length of the pile.

SE-448,177 and WO-92/14885 disclose quite different types of concrete pile joints, in which the lock pins consist of pile lengthwise arcuate bolts in corresponding grooves, respectively, and double-saloon-to-pivoting rods having cross-sectional shape. These solutions have the same problems and drawbacks 15 as the common structures described above.

GB-2 206 367 discloses a slightly different pile junction, which consists of only one junction member in the middle of the pile cross-section. This requires fittings of considerable thickness and the rat-20 rigging is quite disadvantageous to buckling. In the first embodiment, the connecting members consist of a connecting loop projecting from the end of the second pile as a male part and a connecting loop embedded in the end of the second pile and attached to the end box as a female part. An interlocking wedge is inserted through the hole of the interlaced loops. According to another embodiment, both piles. The end has a recess formed of a sheet material as a female part and a hole across the pile, whereby the piles are joined to each other by two locking wedges passing through a male elongated but otherwise loose male sink. In both the first and second embodiments, a female portion or two * female portions respectively containing recesses that are very easy to freeze but very difficult to clean from ice are used. Due to the central location of the connecting members, a locking wedge must be used in the publication, which further increases the material of the connecting loops; thickness due to high force. The wedge-shaped locking pin also tends to loosen when piling on the ground. In addition, the be- · 35 ton casting of the pile containing the female coupling member is problematic because the structure has holes and openings through the concrete, which require formwork members for casting the concrete. Another disadvantage of the second embodiment is that installing a loose loop on the site is both difficult and dangerous. Loose accessories may also disappear. As described in the prior art, the parts described in the disclosure must be machined. It is impossible to correct the base plate according to the solution described further and to get the connecting members exactly parallel to the length of the pile if the base plate has been bent or become curved during manufacture or subsequent processing. This solution is thus both expensive and impractical.

It is an object of the invention to provide a rigid and strong joint between reinforced concrete punching piles. A first object of the invention is to provide such a joint where each end of the pile entering the joint contains as small as possible recesses for the joining members in which the water could freeze. Also, according to the goal, there should be no long through holes in the end portions of the piles where the water could freeze. Furthermore, according to this object, any recesses should be shaped and located so that they can be easily cleaned of any ice formed. Another object of the invention is to provide such a Jat-15 colitis which is as strong as possible against buckling. A third object of the invention is to provide such a joint which, if necessary, could be dismantled and preferably in a manner similar to that which it is assembled, but which still has no tendency to loosen and detach when impacted by impacting the pile to the ground. A fourth object of the invention is to provide such a joint, which could also be made non-disassembling, if the disassembly option is not required or is disadvantageous in some special applications. A fifth object of the invention is to provide such a joint, in which the connecting members, i.e. the parts to be attached to each other in the end-to-end piles, could be made either co-:. without machining or at least as little machining as possible while still achieving sufficient or good accuracy. A sixth object of the invention is. '. 25 such a joint, which avoids any such cross-section of the pile length; _ * parallel welds where tensioning is applied when the piles are joined together.

It is a seventh object of the invention to provide such a joint which is not cast in concrete. ·: It would be necessary to consider holes through concrete, at least in all embodiments. An eighth object of the invention is to provide such a joint where, if necessary, a bottom or bottomless end box could be used. With respect to this T 1, * it is acknowledged that from the seventh object of the invention the following can be achieved:. I have to compromise, ie some form (s) of mold may be needed for concrete casting. It is a ninth object of the invention to provide such a joint, in which the connecting members are easily obtained with the required precision in connection with the casting of the reinforced concrete pile: 35 and also a possible bent base plate. It is a further object of the invention to provide a joint which is as simple and simple to fabricate as possible and which, even under difficult conditions, to make a joint on site, would be quick, simple and secure.

The problems described above can be eliminated and the objects defined above can be satisfactorily accomplished by a joint according to the invention, which is characterized by what is defined in the characterizing part of claim 1.

The main advantage of the invention is that in the joint structure according to the invention, the joining members of the various piles can be simply made of a suitable 10 types of steel bars either by bending, which also acts as the same gripping steel, or by using a longitudinal and thus strong and durable welding hook. Machining steps or pressing steps are not required to finish any single small surface area, either at all or at most in volume. Another advantage of the invention is that in the joint structure according to the invention there are only shallow and outwardly open areas with a large surface area in which the water does not easily lie down and thus does not freeze, for the locking pins and locking pins for the locking pin and the opposite pile. However, if water freezes in the troughs, it is very easy to clean the trough due to its round shape and transparency. It is also an advantage of the invention that the connecting members according to the invention protrude very little from the ends of the piles, so that they are not easily damaged even when struck. In addition, the only surface whose surface is; it is important, that is, the inner surface of the splice loops, points in the direction of the pile on which it is attached, being quite well protected. The joint according to the invention is also strong against, for example, pile buckling, because the joint has several spacers. 25 points apart and at least at a distance from the center line of the pile. This spacing between the joints provides good properties for the combination of connected piles, while at the same time reducing the material thickness of the joints without compromising strength. It is also an advantage of the invention that the detachable or, alternatively, non-detachable locking pins can be provided in the structure, so that the pile head can be formed not only with the bottom plate i, but also completely or partially bottomless as required. A further advantage of the invention is that the protruding splice loops allow them to be oriented in the direction of the longitudinal sides or edges of the pile, and to grip thereon to correct for possible curvature of the base plate etc. and to obtain the base plate perpendicular to the length of the pile. For special conditions, the present invention may be used to provide; in the structure, the connecting members are made without problems, for example, of stainless steel, since there are few exposed surfaces and there is no need to weld different types of steels to each other, which would cause problems.

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The invention will now be described in detail with reference to the accompanying drawings.

Figure 1 shows a structure of a first embodiment of a rigid joint according to the invention, including one junction at a plurality of junctions at the end of a reinforced concrete pile, taken in axonometric and exploded view. The figure also shows a first embodiment of the first and second jointing loops according to the invention, wherein the loop is made of reinforcing steel.

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Figure 2 illustrates the structure of another embodiment of a rigid joint according to the invention, including one junction at a plurality of junctions at the end of a reinforced concrete pile, taken axonometically and in an exploded view, such as Figure 1.

Figures 3 to 6 show different possible positions of the jointing loops of the invention, and thus the connection points and locking pins, in the cross-section of the reinforced concrete pile, seen in the longitudinal direction of the pile and in the plane of the interface;

Figure 7 shows a second alternative embodiment of the first and second jointing loops according to the invention, in which the loop is connected to a reinforcing steel. ·. seen perpendicular to the plane of the joint and in the same view:. 8.

Fig. 8 shows a third and a second joint of the invention according to the invention; / alternative embodiment wherein the loop bar material at the same time provides the reinforced concrete steels as seen in a direction perpendicular to the plane of the joint and with the other portions removed from the V direction of Figure 1.

Fig. 9 shows a fourth and fourth embodiment of the first and second jointing loops according to the invention, in which the sheet material of the loop is joined to the bonding steel, as seen perpendicular to the plane of the jointing loop and in the same view as Fig. 8.

Fig. 10 is a cross-sectional view of one interface according to the invention; 3 and 4 in a plane perpendicular to the center line of the connecting loops.

112816 6

Fig. 11 shows a longitudinal section through one of the connection points according to the invention, corresponding to the embodiment of Figs. 4 and 9, in the plane parallel to the center line of the joining loops, along section I-I of Figs.

Figure 12 shows in general and in principle the structure of a reinforced concrete pile including the connecting members according to the invention, in longitudinal section of the pile.

Figure 12 depicts a general view of a reinforced concrete pile and its main components. First, in such a pile, PI, P2 has at least two, but usually four longitudinal concrete bars, i.e. pile end steels 29, which preferably extend uniformly over most of the pile length. Depending on the pile dimensions, these reinforced concrete reinforcing bars 29 extend from about 40 mm to about 500 mm from the pile end surfaces 10. A spiral hook 32 is formed around the combination of the reinforced concrete reinforcing bars 29 to form a coiled coil or network around the reinforced concrete 15. In addition, at least one end of the pile, but usually at both ends, K1 and K2 have some type of end-box as well as connecting means for extending the piles, i.e. to end-to-end, to each other with a rigid joint as needed. The remainder of the pile material is concrete 27, which is bonded to the main concrete bars 29, the threaded hook 32, the end boxes, and the connecting members. Typically, 20 reinforced concrete pile piles have a length of several meters and a square cross-sectional shape, typically between 2001200 mm and 3501350 mm. However, other size and cross-sectional piles, such as round and hexagonal piles, are sometimes very rarely used.

The reinforced concrete piles of the type described above, i.e. the end ΚΙ, K2 of the reinforced concrete piles entering into the end joint of each of the reinforced concrete piles, comprise a substantially straight end: surface 10, in particular planar end portions 10 which abut against each other. In addition, at the ends of the piles ΚΙ, K2 are firstly connecting first planar connecting loops 1 transverse to the longitudinal direction Lp of the piles and second interconnecting loops 2 forming a transverse hole 2 perpendicular to the longitudinal direction Lp of the piles.

These junctions 1, 2 extend in the finished junction longitudinally · '' with respect to each other and are located substantially parallel to each other to form junction 9. At each junction 9, where the planes T1 and T2 of junction 35 are at least substantially parallel and junction 2 intermittently, the holes 3, 4 of these connecting loops are aligned with each other in Lt.

Note that reference numeral 9 designates interfaces in general, when it is not necessary to distinguish between different interfaces and specified by reference numeral 112816 7 9a, 9b, 9c, 9d is used only to distinguish one or some of the interfaces from other interfaces.

In addition, the connecting members comprise locking pins 6 which pass through the holes 3, 4 in the line L1 with the connecting loops 1,2 and 2 in the interlaced position. The locking pins 6 are arranged to be positioned transversely to the length M and preferably perpendicular to the length Lp of the pile. In the joint of the invention, the locking pins 6 are preferably straight in cross-section and substantially straight in cross-section and of length M. Such a locking pin has no tendency to loosen and detach from the holes 3, 4 of the connecting loops when the pile assembly P1 + P2 formed by a rigid joint is struck to the ground and the locking pin does not need to be positioned around its centerline Lt in its correct position. The locking pin diameter G2 is then substantially equal to the diameter G1 of the pin hole 31 formed by the holes 3, 4 of the connecting loops together. Of course, the locking pin 6 can be provided with e.g. narrow longitudinal ridges and grooves having ridges having an outer diameter slightly greater than the diameter of the pin holes G1, whereby the partially plastic and partially elastic deformation of the ridges locks the locking pin 6 effectively. Another way to secure the locking pin 6 in place is to form a pin inlet end 36 with a longitudinal groove or recess of the locking pin and to insert a wedge with the tip pointing inside the pin in the direction of the shaft portion and; in the same direction as the inlet end. When the wider end of the wedge 21 is arranged to strike the abutment surface at the bottom of the hole in the pile PI, P2 when the locking pin is inserted, the inlet end portion of the locking pin expands and is pressed tightly against the inner surface 7 of the mesh holes 3, 4. Other cooking methods are also available. These locking pin protectors can be used in conjunction with the embodiments of Figures 3-4 and 6. If, on the other hand, the locking pin 6 is to be detached, if necessary, for example, in the embodiments 5 and 6, through holes 1, 4 in the connecting loops 3, 4 are provided through holes P1, P2 so that the locking pin is opposite the inlet 11! from the direction F2 To be driven away from the pin hole 31 formed by the holes 3, 4 in the connection loops. In the embodiments of Figures 3-4 and 6, the length of the locking pin is approximately half or slightly shorter and the embodiment of Fig. 5 is approximately 35; R or slightly shorter.

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According to the invention, at each junction 9 at least K2, K1 at the end of the first reinforced concrete pole P1 of the joint, at least two first 1282816 8 seam rings 1 and at the end ΚΙ, Κ2 of the second reinforced concrete pile P2 at least two second seam rings 2. an interface 9a, 9c or 9b, 9d arranged at a support distance W from the centerline 13 or the bisector plane 12 of the pile.

However, even if the connection points 9a to 9d are at a support distance W from the bisector plane 12, they are always all at a substantial distance from the center line of the pile PI, P2, although this distance is different from said support distance W. The bisector plane or bisector planes 12 are plane and normally mean two such bisector planes perpendicular to each other, which are also perpendicular to the side surfaces 13a-13d of the piles in the figures. If the pile has a non-square cross-sectional shape or a rectangle, the bisector planes defined above will, of course, be suitable for the curved or otherwise angular exterior surface of the pile.

15

Thus, connection point 9, as defined above, means the point where the first connection loops 1 or second connection loops 2 projecting slightly from the end surface 10 of the second pile P1 and the first connection loops 1 or second connection loops 2 slightly projecting from the end surface 10 of the second pile P2 the holes 3 in the first splice loops and the holes in the second splice loops align with and line Lt to provide a pin hole 31 which y. thus passes through and through the first two connecting loops 1 and two second connecting loops, holes 3, 4. This alignment with the straight line means that the line Lt also forms the center line of the locking pin 6 when it is inserted into the pin hole formed by the holes 3, 4 together. It is clear that each

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; , * There may be more than one splice loops 1 and 2 at the base, there may be three or '; 'Either one or both, so that the first and second jointing loops 1, 2 can always have the same number or different numbers at each junction, as long as each is at least two.

A: 30 i: At each junction 9, the second splice loops 2 are at least • apart from the first splice loops 1, and the first splice loops 1 are at least the maximum thickness S2 of the second splice loops 2. If the first splice loops · · 35 the distances between the two meshes and / or between the second meshes are equal to the maximum thicknesses S2 of the second meshes and correspondingly the maximum thicknesses SI of the first meshes are tight fit between the meshes in the direction of the centerline Lt. the aforementioned distances, that is, the distances a bit, that is, a clearance greater than the maximum thicknesses S1 and S2, this clearance may be of the order of 1 mm to 10 mm, such as 2 mm to 5 mm. to 20 mm or so large that, for example in the case of Fig. 5, the first and second splice loops are evenly distributed in the direction of the locking pins 6 over the entire pile thickness. In the embodiment of Figure 5, the four interface points 9a-9d described herein are effectively reduced to two interface points, one on the other side of one bisector plane 12 and the other on the other side of this bisector plane 12, the first and second loops 10 each. In some cases, this may mean that the clearances are greater than said maximum thicknesses, whereby the said distances, or distances, of the splice loops may be many times the maximum thickness. However, very few placement of jointing loops can present a problem in maintaining the direction of the locking pin when it is inserted. Thus, it is now believed that the stated distances, i.e. distances, of the slip loops 15 are appropriate to be kept less than twice the maximum thicknesses, but otherwise as defined above. The large distances of the splice loops described above are not shown in the figures and the small clearances are again inseparable. At each junction 9, one of the first junction loops 1 is at a first distance A1 from the lock pin 20 entry 11 and one of the second junction loops 2 is a second distance A2 from the lock pin entry 11. This second distance A2 is at least greater than or equal to the SI smaller than the first distance AI. The difference between these distances AI and A2. ·. Preferably, 25 follows the same clearance rule as described above in this paragraph. Taking into account the above described the first connecting loops. 'The distance and the distance between the other loops are in each individual connection? Thus, in step 9, the first splice loops 1 in the direction of the centerline of the holes 3, 4 are at different positions than the second splice loops 2, allowing the first and second splice loops to overlap while the lateral surfaces 8a-8d of the two line with each other, the pile joint-: i: is therefore straight over the rigid joint.

According to a preferred embodiment of the invention, each jointing loop 1, 2 is made up of 35 bar-like steel materials, whereby there are different v: alternatives for the detailed design. Can be e.g. use as a material the conventional concrete used; '. I, and bending it into a U-shape, whereby the inner surface of the U-bend forms the resulting hole 3, 4 or a portion thereof as shown in Figure 2. The mainly parallel branches 19a of this 112816 10 U-shaped body extending from the pile end surface to the inner parts of the pile form at the same time a single reinforcing steel steel 16 for the rigid joint joining means. would have a sufficiently smooth sliding surface when struck. Alternatively, as shown in FIG. 7, U-shaped loop pieces 30 may be used, with short legs 19b facing one side of one brushed steel and welded 20 along the brushed steel and legs 19b in this conventional brushed steel forming one of the rigid joints The inside surface of the bend of this U-shaped loop piece forms the hole 3, 4 of the splice loop, and the piece can be made either by machining the solid piece to this shape or most preferably by bending a rod or section of rod having the desired cross sectional shape. The length La of the loop 30 in the direction of the gripping steel 17 is at least three times 15 times the thickness of the material + the diameter G1 of the hole 3, 4 and at most six times the thickness of the material + the diameter G1 of the hole 3,4. A third particularly preferred alternative is to bend a long square bar or rectangular bar or angular bar 33 into an appropriate U-shape, whereby the inside surface of the bend forms a hole 3, 4 in the connecting loop. In addition, both ends of this bar 33 forming branches 19c are axially twisted 1 and 8, or spiral and / or formed to include bends 22 and / or depressions and projections, as schematically shown in Figure 12. In this way, the prongs 19c of the substantially U-shaped angular bar 18 remain in longitudinal direction. - even under tensile or compressive stress with excellent adhesion to the concrete, so that the 25 arms act as one of the adhesive concrete joints of the rigid joint joints; as a fourth 18. As a fourth alternative, as shown in Fig. 9, a loop is formed · ·. 'is to leave the plate body and machining a hole 3, 4 therein, and further along this hole in line with the peripheral recess 35 to form a loop I · * ·' 34 with two arms 19d welded thereto by welds 20 to the ridge 30 In each of these cases, tar-ν ': the length Lb of the felt concrete 16, 17, 18 measured from the pile end surface 10 inside the pile v: in any of the ways described above, substantially less than the length Lp of the pile PI, P1 , but at least equal to the ul-_ '' 'of the pile; This diameter Lb is usually greater than 35 pile diameter R or one and a half times R or twice R or three times R,::: but usually less than ten times R or six times R. Ordinary •, '· reinforced concrete steels lengths Lb are between 350 mm and 700 mm. The material S1, S2 of the U-shaped splicing loops 1, 2 provided in this manner are typically of the order of 10 mm to 20 mm and preferably of 12 mm to 15 mm. The reinforcing reinforcing steels 16, 17, 18 accept the forces resulting from the rigid joint but do not contribute to the actual strength of the pile itself, for which the reinforced concrete reinforcement 29 is contained within the pile concrete 27 as previously described in this text. In fact, the end portions of the reinforcing steel 16, 17, 18 facing the pile and the end portions of the reinforced concrete bars 29 towards the end surfaces should be somewhat interlaced in the reinforced concrete pile, but only for a portion of the length Lb of the reinforced concrete. In the interlocking region 10 of reinforced concrete steels 16, 17, 18 and reinforced concrete irons 29, they should be close to each other, but preferably not in contact with each other, and in addition, reinforced concrete irons should be approximately between the reinforced concrete steels and the nearest pile side surface. Thus, reinforced concrete punching piles typically have at least the same amount of reinforced concrete and reinforced concrete steels. Only with the structure and arrangement described, these punch piles provide sufficient strength and flexibility at the same time.

The maximum thickness S1, S2 of the loops extends substantially around the entire circumference of the loops 1, 2, i.e. the material surrounding the hole in the loops is approximately uniform in thickness, as is always the case for circular, rectangular and square bars. This uniform thickness promotes interlacing of the joint loops as well as keeping them clean from ice and, if necessary, cleaning. Preferably, the portion 7 of the inner surface of said hole 3, 4 of the jointing loops, which points in the direction of the reinforced concrete pile PI, P2, which serves as the support base for the jointing loop in question, is half-shaped. 25 circles, with> * 'of overlapping loops at each junction 9. said semi-circles together forming a circular hole 3, 4 for locking pin 6. This emergence of the circular pin hole 31 formed by the interleaved first and second connecting loops 1, 2 and aligned with the holes 3,4 in the line L 1 is apparent and is particularly clear from FIG. 8.

30; In addition, the first splice loops 1 according to the invention have the second splice loops 2 having a small protrusion E from the planar end surface 10 of the pile. at the ends of the opposing piles PI, P2 at the ends of the joining 6 ''. has substantially the same protrusions E, which means that all the joining loops 35 1, 2 have substantially equal protrusions E from the portion of their pile as the mounting base 10. In this case, the center lines Lt of the holes 3, 4 of the connecting loops and thus also the center line of the locking pin 6 are located at a portion of the planar end surface 10 112816. With this solution, the risk of damage to the splice loops is low, which is facilitated by the structure of the splice loops described earlier.

According to the invention, the rigid joint may have two junctions 9a, 9c or 5 9b, 9d, the holes of which in the junction loops are parallel to each other. Such a connection can be conceived by means of Figures 3-5, leaving only two connection points opposite one another in the diagonal direction. The joint may and often has four junctions 9a to 9d, each at a support distance W from at least one of the previously described bisector planes 12. In the embodiments of Figures 3 and 4 10, successive junctions 9a 9d are at one support distance W from each 13, while at the other bisector planes the junctions are tangent although the centers of the junctions are at different support distances W from these bisector planes. In the embodiments of Figs. 6 is shown. Figure 5 illustrates an alternative arrangement in which each of the two lateral connection points 9a and 9b, 9c and 9d are aligned in pairs with each other to form two pairs of connection points 23a and 23b. In each pair of junctions 23a, 23b, the lines Lt of the holes 3, 4 of the connection loops 1, 2 are parallel, i.e. the line Lt of the first pair 23a is parallel to the line Lt of the second pair 23b. When:. in pairs of junctions, the previously treated distance of the first junction loops and the second junction loops 1, 2 is increased to a greater extent than the mesh; the maximum thicknesses S1, S2, each of the two pairs of junctions 23a, 23b of the aforementioned junctions ultimately only constitute one junction, since their parts can no longer be separated from each other. Each pair of junctions 23a and 23b is at a distance W from the bisector plane 12 therebetween, but in the case of Figure 5, the individual junctions 30 are also at a distance from the other bisector plane. The latter - •. · However, this condition is not required to be met, especially if coupling pairs 23a; : and 23b extend in the direction of the bisector plane between them to a substantial portion of the pile. ·. with the pile having a substantially square cross-section and a joining _ * ': comprising two or four junctions, at each junction 9, alternately, said planes T1, T2 of the junction loops are substantially parallel to or one of the sidewalls 8 or 8 and the line Lt of the mesh loops · perpendicular to this side surface, as shown in Figures 3-5, or said planes T1, T2 of the mesh loops are substantially parallel to the longitudinal diagonal 15a, 15b of the reinforced concrete pile 112816 13 as shown in Figure 6. and 6, openings may be provided on the locking pin through the pile material, whereupon the locking pins 6 may be removable if necessary by hitting the insertion direction F1 relative to the opposite release direction F2.

5

At the ends ΚΙ, K2 of the reinforced concrete piles there are end boxes 24 comprising a frame 25 of a circumferential and plate-like material 26 surrounding the pile ends P1, P2 along the side surfaces 8a-8d of the pile, and possibly a base plate 26 perpendicular to the side surfaces. in the region of each junction 9, a trough recess 5 parallel to said line Lt of holes in junctions 1 or 2 and having a depth D from the planar end surface 10 of the pile P1 or P2 at least equal to protrusion E of its pile P2 at this junction or P1 of the planar end surface 10. The width B of the recess 5 is at least equal to the width C of the splice loops in the direction of the planar end surface 10 of the piles. The recess 5 extends over at least one of the sidewalls 8a-8d of the reinforced concrete pile, either with the same cross-section B, D as defined above, or alternatively with a smaller cross-section, such as nearly locking pin cross section G2, as shown in Fig. 5 extend from one side surface 8a, 8b, 8c, 8d of the pile to one side surface 8c, 8d, 8a, 8b or 8b, 8c, 8d, 8a in the direction of said lines L1, allowing the locking pin 6 to be pierced as previously described.

:. According to the invention, the end-box 24 of the reinforced concrete piles may be completely bottom-plate; , 25 inches, with the trough recesses 5 as well as the planar end surfaces 10 being '. . made entirely of concrete material 27 and the end box having Alternatively, the end box 25 may alternatively have a bottom plate, wherein at least the planar end faces 10 are formed of a metal plate or metal cast which "·" forms a base plate 26. For example, the bottom plate 26 is welded to the frame 25.

In this case, the trough recesses 5 are formed either of concrete material; ; list 27, whereby base plate 26 provides only planar end faces 10:: portions, or alternatively metal plate or metal casting 28, whereby base plate 28 ... covers both planar portions and recesses of end faces 10, in the case of end box 26 or 28 the splice loops 1 and 2 are typically 35 welded to the base plate, regardless of the structure of the splice loops. If the bottom plate 26 is of a type that leaves the trough recesses 5 open; , why delimited by concrete, weld joints to the bottom edge of the base plate which is bounded by a recess or a recess in the base plate. In the case of a fully covering base plate 28 of the end face 10 112816 14, the splice loops are welded to the holes of the base plate through which the splice loops or their branches 19a, 19b, 19c or the silicon piece 34 itself pass.

5 For the joint, first, the first end K1 of the pile may have only the first jointing loops 1 and the second end of the pile K2 only the second jointing loops 2. The first and second jointing eyes 1, 2 are otherwise similar except that their distances from the locking pin entry as defined as necessary for their intermittent passage. Thus, in this method of positioning the splice loops at the first end of the pile, all the splice loops 1 at each junction are at distance A1 and A1 + S2 and possibly A1 + 2 * S2, etc., if the junctions have more than two junctions at the junction 11. 2 at each junction are at distances A2 and 15 A2 ± S1 and possibly A2 ± 2 * S1 etc., at entry 11. However, in the above solution I have to check the correct type of pile head, so the more advantageous solution is to have K1 and K2 at both ends of the pile. has both first splice loops 1 and second splice loops 2, forming an even number of splice points 9 with the second and en-20 first splice loops 2 and 1 of the second pile entering the splice respectively. In this arrangement according to the invention, at each other junction, e.g. junctions 9a and 9c, or at the second junction, e.g., 23a, there is a distance · of the first junction loops. A1 and A1 ± S2 and possibly A1 ± 2 * S2 etc., if there are more than two splice loops at the junction, away from the junction 11. Correspondingly, there are; v. 25 at every other junction, e.g. junction 9b and 9d, or junction '. '. in the second pair of positions, e.g., in pair 23b, are the distance of the second connecting loops 2; det A2 and A2 ± S1 and possibly A2 ± 2 * S1 etc., if there is more than one '; '; In this embodiment, the ends of the piles K1 and K2 are similar and it is necessary to rotate the pile 30 P2 at most about the center line 13 to align its first connecting loops 1 and second connecting loops in direction F3 the second pile P1 to the second splice loops 2: and respectively to the first splice loops. The locking pins 6, · · are then struck. 1, as shown in Figures 1 and 2.

35 When casting a reinforced concrete pile and when using a jointing member according to the invention, and in particular a jointing member comprising four spaced apart and spaced apart: ·. 1, 2 and 112816 15 9, spaced apart between the pivot points 9 or two of the pile center line 13 and the support distance W from the pile bisector plane 12, may be grasped by means of suitable lugs which are not required herein, Take control of the concrete casting mold. When the locking members are tightened, they place the connecting loops 1, 2 in the correct position, i.e. parallel to the length of the pile, and at the same time pull or force any base plate if it has curvature or twist, so that the base plate 26, 28 or more precisely the end surface 10, becomes straight, i.e., high-planar, and at the same time perpendicular to the center line 13 of the pile PI, P2.

Claims (13)

A rigid extension joint for joining end-to-end reinforced concrete piles, wherein each end of the reinforced concrete pile (PI, P2) entering the joint on its end surface (10) comprises sections which abut against the rigid extension joint. each other; and joints, which comprise: - a first planar joint (1) forming a shark transverse to the longitudinal direction of the palms (Lp) and a second planar jointing eye (2), which in the joint extends overlapping in the longitudinal direction of the piles and is adjacent substantially parallel so that they form a joint point (9), where the heel (3, 4) of these joint loops is in line (Lt), 10. the extension joint has at least two such joint points arranged at supporting spacing (WO from pel s center line (13) or bisectric plane (12), - reading pins (6) extending through the aligned joint eyes, characterized in that each joint eye (1,2) comprises: of reinforced concrete (PI, P2), or - loop pieces (30, 34) connected by welds (20) to the extension concrete support pieces (17) in the extension, or - an edge bar (33) which is bent in U-shape and whose branches (19c) corresponds to the length of the gripping concrete frame pieces; that both said first joint eyes (1) and said second joint eyes (2) have a projection (E) from said section in the end surface (10) of the pile; and that at least two first flat joint eyes (1) and at least two second flat joint eyes (2) are provided at said joint points (9). j. Stiff extension joint according to claim 1, characterized in that said section. at the ends of the reinforced concrete piles are flat; and that within the area of each joint, point (9) at the end of the reinforced concrete pile, there is a latch-shaped outlet (5) which is:. - parallel to said line (Lt) in the heels of the joint eyes (1 or 2) and whose depth (D) from; the flat end surface (10) of the pile (P1 or P2) is at least as large as the protrusion (E) of the joint eyelets (2 or 1) in the opposing pile at this joint point from the flat end surface (P2 or PI) of the joint. ) and width (B) are at least equal to the width of the joint eyes:: (C) in the direction of the flat end surface (10) of the piles, and which: - extend at least to one of the side surfaces of the reinforced concrete piles (8a-8d) . ; '3, Rigid extension joint according to claim 1 or 2, characterized in that at each joint point (9), the second joint eyes (2) are spaced correspondingly': at least the maximum thickness (SI) of the first joint eyes (1) and the first joint eyes (1). .: 35 lies at a mutual distance corresponding to at least the maximum thickness (S2) of the other joint eyes (2). 112816 20 Rigid extension joint according to any of claims 1-3, characterized in that at each joint point, some of the first joint eyes (1) lie on a first distance (AI) from the reading point's entrance point (11) and some of the second joint eyes (2). at a second distance (A2) from the leg end point (11) of the reading pin, the second distance (A2) being support than the first distance (AI) corresponding to at least the maximum thickness (SI) of the first joint eyes or, alternatively, less than the first distance (AI) ) corresponding to the maximum thickness (SI). Rigid extension joint according to claim 3 or 4, characterized in that: alternatively: 10. only the first reading eyes (2) and the second end of the fur (K2) have only first reading eyes (2); or - at each end of the pile (K1 and K2) there are both first seams (1) and second seams (2), which form an even tai seam (9). Rigid extension joint according to claim 3 or 4, characterized in that the maximum thickness of the joint eyes (S1, S2) extends substantially over the circumference of the joint eyes (1, 2); that the section (7) of the inner surface of said heel (3, 4) in the joint eyes which is directed towards the reinforced concrete pile (PI, P2) which forms the solid foundation for the joint joint concerned is in the form of a semicircle; and that said semicircles in the joint eyes that overlap at each joint point together form a circular heel (3, 4) for the reading pin (6). Rigid extension joint according to claim 1, characterized in that the protrusion (E) of the joint glare (2) is substantially equal to Large from the flat section of the end surface (10) of the pelvis, whereby the center line of the heel (Lt) and thus also the centerline of the reading pin (6) at end section flat section. ': 25 Rigid elongation joint according to claims 1 or 6 or 7, characterized in that:: the reading pins (6) have substantially straight cross-section and straight length (M) and substantially uniform thickness. : 9. Rigid extension joint according to claim 3 or 4, wherein the reinforced concrete pile,,: has a substantially square cross section and the extension joint comprises two or. Four joint points, characterized in that at each joint point (9), the alternate joint (T1, T2) is substantially parallel to a side surface (8a or 8b or 8c or 8d) of the reinforced concrete pile and the line (Lt) of joint joints. heel: is perpendicular to this side surface; or ": - said joint of said joint (T1, T2) of the joint eyes is substantially parallel to the diagonal (15a, 15b) between the longitudinal edges (14) of the reinforced concrete pile. Rigid extension joint according to claims 1 or 3 or 4, characterized in that: - the U-shaped curved concrete frame pieces (16) have branches (19a); - the loop pieces (30, 34) have branches (19b or 19d) and are connected by weld joints 5 (20) to the gripping concrete support piece (17) in the extension of the reinforced concrete pile; or - the length (Lb) of the branches (19c) of the curved U-shape curved bar (33) corresponds to the length of alternative gripping concrete pieces and said branches (19c) comprise an axial thread (21) or spiral shape and / or bends (22). ) and / or recesses and bursts, forming gripping concrete pieces (18) in the extension. Rigid extension joint according to any of the preceding claims, characterized in that the joint preferably has four joint points (9a-9d), which are in pairs in line between each other, the lines (Lt) in the pair (23a, 23b) of joint points being parallel. that the bell-shaped receptacles (5) extend parallel to the said lines (Lt) of the tail from one side surface (8a, 8b, 8c, 8d) to the other side surface (8c, 8d, 8a, 8b or 8b, 8c, 8d) , 8a) so that they make it possible to sew the reading pin (6). Rigid extension joint according to any of the preceding claims, characterized in that the reinforced support rails at their end ends (ΚΙ, K2) have end joints (24) which comprise a frame (25) of disc-like material surrounding the rails along the side surfaces and optionally 1 a base plate (26) which is substantially perpendicular to the side surfaces. Rigid extension joint according to claim 1 or 2, characterized in that where the end face (24) of the reinforced concrete piles is (A) without a bottom plate, the latching recesses (5) are formed in the flat end surfaces (10) of concrete material (27); or {B} provided with a bottom plate, 25. the flat end surfaces (10) are formed of metal sheet or metal casting, which is the bottom plate (26) and: - the rafter-shaped recesses (5) formed either of concrete material (27) or alternatively of a metal sheet or metal mold (28).