FI116474B - Connection of pieces such as reinforced concrete piles - Google Patents

Abstract

A joint for joining reinforced concrete pillars (10a, 10b) together, wherein a first connecting element (20a) comprises a cylindrical projecting part (30) provided with an annular groove (31) and a second connecting element (20b) consists of a cavity (40, 63) provided with an annular groove (41, 65). An annular spring (50) interlocks the grooves (31, 41, 65). The groove of the joining element of at least one of the objects to be joined is provided with a wedge-like part (34, 44) on which the spring-like locking element (50) is wedged, forming a joint free of backlash. <IMAGE>

Description

1,116,474

BACKGROUND OF THE INVENTION FIELD OF THE INVENTION

The invention relates to a joint between two interconnected bodies, such as reinforced concrete piles 5, comprising a first joint member at the end of the first joint member formed by a circular pin having an annular groove, a second joint member at the end of a second joint member is an annular groove, a 10 - severed spring ring that locks the annular groove of the first connecting member into the annular groove of the second connecting member.

BACKGROUND OF THE INVENTION

There are many different solutions for reinforced concrete pole joints. In general, a joint method 15 is used in which the ends of each of the piles to be extended have four guide and locking pins with transverse holes in the longitudinal direction of the piles, which enter into corresponding recesses at the end of the opposite pile when the piles are The joint is locked by striking from the side the locking wedges through the transverse holes at the ends of the piles and through the holes of the guide and locking pins 20 at the corresponding position. However, this method of connection has proved to be difficult and laborious in practice. The transverse holes at the ends of the piles and the holes in the steering and locking pins are not always * aligned, making it difficult to hit the transverse locking wedges. In this case, one or more of the joint locking wedges are often omitted, whereby * * * joining piles becomes weak.

·: ··: 25 •; Since the aforementioned types of joints have proved to be very practical in practice. "·., Efforts have been made to develop different types of quick coupling joints also for reinforced concrete pole joints.

· Patent Nos. FI-47503, SE-214150 and SE-178840. According to one solution! * The connecting member at the end of the 30 piles to be extended includes a round pin which fits 1; ' 'Into a circular cavity at the end of the second pile having a ring groove and a spring ring. Tapin '. · The head is shaped conically so that when pushed into the recess, it opens and tenses: a spring ring in the recess. When the pushing movement at the end of the interconnected. *. the ends of the reinforced concrete piles are pressed against each other so that the spring ring is dropped in the pin ''. 35 and locks the joint.

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However, the above-mentioned, in principle easy-to-use quick coupler type joint has not proved to work in reinforced concrete pole joints. One of the reasons is that in the case of extension of the piles, the piles must be tightly joined to each other and completely parallel to each other before the spring ring 5 in the recess of the joint at the end of the other pile locks into the annular groove of the pile. However, this is difficult because the coupling members cannot have large clearances. In this case, even a slight manufacturing defect in the joints of the piles, deformation caused by the impact or debris in the joints may prevent the joint from locking. On the other hand, if the clearances of the connecting members are increased, then the joint will not be sufficiently rigid and sturdy.

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PURPOSE OF THE INVENTION

It is an object of the present invention to provide a joint for piles which does not have the above disadvantages.

15 CHARACTERISTICS OF THE INVENTION

The joint of the two joining members according to the invention, such as reinforced concrete piles, is characterized in that the sidewall of the annular groove of at least one connecting member forms an angle with a plane perpendicular to the longitudinal axis of the circular pin or cavity. to each other.

': EMBODIMENTS OF THE INVENTION OF THE INVENTION

A preferred embodiment of the joint according to the invention is characterized in that: * the spring locking member is a truncated spring ring having a cross-section of: •: ·: 25, the conical surface of the spring ring being substantially equal to •; · · The conical surface of the annular groove of the coupling member, "". - and that at the joint the conical wedge surface of the spring ring and the conical surface of the annular groove of the coupling member.

;;. Another advantageous embodiment of the joint according to the invention is; 'characterized in that the first connecting piece is a reinforced concrete pile at its end': the connecting member is formed by a pin having a circular cross-section with an annular groove, '35 - the second connecting piece being a rock tip with a connecting recess having an annular groove, 116474 3 and that the connecting members of the reinforced concrete pile and the rock tip are locked together by a spring ring supported by annular grooves of the connecting members, at least one of which has a conical wall.

5 APPLICATION EXAMPLES

The invention will now be described by way of example with reference to the accompanying drawings, in which:

LIST OF FIGURES

Fig. 1 is an axonometric view of the ends of two reinforced concrete piles and their respective connecting members, in partial section.

Figure 2 is a vertical sectional view of the end of two reinforced concrete piles and their compatible connecting members.

Figure 3 shows a vertical sectional view of a joint of reinforced concrete piles.

Figure 4 corresponds to Figure 3 and shows a connection of reinforced concrete piles according to another embodiment.

Figure 5 schematically shows a sectional view of a joint of two pieces according to a third embodiment.

Fig. 6 corresponds to Fig. 5 and shows a joint of two pieces according to a fourth embodiment.

Figure 7 shows a vertical sectional view of a joint between a reinforced concrete pile and a rock tip.

'' Fig. 8 corresponds to Fig. 3 and shows the connection of reinforced concrete piles with a fifth * »•. ': According to an embodiment.

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: ··: 25 DESCRIPTION OF THE FIGURES

Fig. 1 shows an extension of two reinforced concrete piles 10a and 10b, where the ends of the piles are close to each other but still separate. The main material of the piles 10a and 10b is concrete 11, in addition to which, as is known in the art, they also contain a great deal; t · t reinforcing steels not shown. Instead, Figure 1 shows ';!.' 30, the structure of the connecting members 20a and 20b of the reinforced concrete piles 10a and 10b.

'; * 4 Each of the connecting members 20a and 20b comprises an end plate 21a and 21b welded thereto: '·· an edge collar 22a and 22b and anchoring steels 23a and 23b welded to the end plates 21a and 21b.

In FIG. 21b is a welded cylindrical recess 40 having an annular groove 41 on the inner surface of the cylindrical jacket. Also, this cylinder 40 is provided with a bottom plate 42. drops into the groove 31 of the projection 30, locking the connection between the connecting members 20a and 20b and the reinforced concrete piles 10a and 10b.

Figure 1 shows that a suitable amount of bonding steels can be added to the circumference of the joining members 20a and 20b according to the strength requirements 10 required for joining the reinforced concrete piles 10a and 10b.

Fig. 2 shows a vertical sectional view of the connecting members 20a and 20b of the reinforced concrete piles 10a and 10b. The projection cylinder 30 connected to the end plate 21a of the upper pile 10a has a conical end 33 and an annular groove 31. The figure shows that the other side wall 34 of the annular groove 31 is inclined to form an angle α with the plane perpendicular to the longitudinal axis of the cylinder Since the projection 30 is a circular cylinder, the inclined wall 34 forms a conical surface. The angle α is at most only a few degrees. For example, a slope of 5 to 10 ° is sufficient for the spring ring 50 to wedge against this surface and to lock the connecting members 20a and 20b together. Instead, in Figure 2, the inner surface of the cylinder 40 of the lower pile 10b's connecting member 20b has a rectangular annular groove 41 in which a truncated spring ring 50 of rectangular cross-section is located.

Fig. 2 shows the letters a and b the distance between the edges of the ring grooves 31 and 41; · * · 25 from the contact surfaces of the reinforced concrete piles 10a and 10b. These dimensions are; · · · Essential for the proper functioning of the connecting members 20a and 20b. In order to "effectively lock the spring ring 50 against the conical surface 34, the dimension a must be less than or equal to b.

Fig. 3 shows the reinforced concrete piles 10a and 10b of Fig. 2 connected to one another and the spring ring 50 dropped into the groove 31 of the connecting member 30 of the upper reinforced concrete piles 10a. compressive stress. Then '. The spring ring 50 wedges against the conical surface 34 of the groove 31. When this extended pile 35 is struck at the end of the upper pile, with each stroke, the spring ring 50 becomes more closely wedged against the conical surface 34, thereby forming a very strong joint.

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Fig. 4 shows an embodiment in which the wedge of the spring ring 50 against the conical surface 34 is further enhanced by the screws 51a and 51b which press the spring ring towards the bottom of the groove 31.

Fig. 5 is a diagrammatic elevational view of a junction of two pieces in which the cylindrical projection 30 is pressed into the cylindrical recess of the piece 40. In this embodiment, both the groove 31 of the cylindrical projection 30 and the spring ring 50 are wedge-shaped in cross-section, that is, both have conical surfaces disposed against one another. The spring ring 50 is then more effectively wedged into the groove 31 by locking the projection 30 and the recess 40 of the connecting members 10 together.

Fig. 6 shows another alternative of the spring ring 50 according to which the spring ring 50 has a cross section.

Figure 7 is a vertical sectional view of the connection between the reinforced concrete pile 10 and the rock tip 60. This joint corresponds completely to the above-mentioned pile connection.

Thus, the rock tip 60 shown may be attached to the end of any pile.

In the rock tip 60, the actual tip portion 61 is connected by a screw 62 to the body portion 63 corresponding to the cylinder 40 of the connecting member 20b at the end of the pile 10b. Within this frame cylinder 63 there is a corresponding recess and annular groove 65 for the spring ring 50. The frame cylinder 63 is connected to an end plate 64 which abuts against a pile end plate 21.

*. '! Fig. 8 shows an alternative joint of reinforced concrete piles 10a and 10b, where: the spring ring 50 is placed in a rectangular groove 31 in the cross-section of the projection 30 in the cross-section of the projection 30. Thus, the mouth 40 of the recess 40 in the piling step. When the projection 30 is inserted: '*': into the recess, the spring ring 50 opens into the groove 41 of the recess 40 and wedges against the conical surface 44. The operation of the spring ring 50 is thus the opposite of the other embodiments described above. In order to only tighten the joint, I t,!. '30, then the inclined surface 44 of the groove 41 of the recess 40 must also in this case be>; on the opposite side.

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: ADDITIONAL NOTES

It will be apparent to one skilled in the art that various embodiments of the invention may vary within the scope of the following claims.

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REFERENCE NUMBERS

10 reinforced concrete pile 11 concrete 20 connecting member 5 21 end plate 22 edge collar 23 anchoring steels 30 projection 31 groove 31 32 bottom 33 end cone 34 groove conical wedge surface 35 abutment 40 recess 15 41 groove 42 bottom 43 cone 44 wedge 45 abutment surface 20 50 spring ring 51 screw cone , · 60 rock points • '· 61 points ·; ·; 25 62 screws •; · · L 63 cylinders. · ·. 64 end plate 65 groove

Claims (3)

A joint between two jointable pieces (10, 60), such as piles, to which joint it belongs an end joint (20a) located at the end of the first jointable piece (10a), formed by a round pin (30), having an annular groove (31), a second splice (20b) located at the end of the second joint (10b, 60), formed by a round recess (40, 63) having an annular groove (41.65 ), a cut-off spring ring (50) which reads the annular latch 10 (31) of the first joint (20a) to the annular latch (41, 65) of the second joint (20b), characterized in that the side wall (34) in at least one the annular groove (31, 41, 65) of the joint member (20a, 20b) forms an angle (a) with the perpendicular plane to the longitudinal axis of the round pin (30) or the depression (40, 63), such that said side wall forms a conical surface, against which the spring ring (50) wedges the reading joint member tensioned at each other. A joint according to claim 1, characterized in that the spring-like reading means (50) is a cut-off spring ring, whose cross-section is wedge-shaped, such that the spring-shaped conical surface (52) corresponds mainly to the conical surface of the annular groove (31) of the joint (30). ), and that the cone-shaped wedge surface (52) of the spring ring (50) and the cone-shaped surface (34) in the annular groove (31) of the joint member (30) are in contact with each other in the joint. •: * · i 25 A joint as claimed in claim 1 or 2, characterized in that: - the first jointable piece (10) is a reinforced concrete pile whose end is located in the end. the joint is formed by a circular pin (30) having an annular latch (31), the second collapsible piece (60) being a rock shoe, the joint being a circular depression (63) having an annular latch (65), 30. and that the joint (30, 63) of the reinforced concrete pile (10) and rock shoe (60) is Iastä at; '' Each other with a spring ring (50) which abuts against the annular rafter of the joint member (31, 65), of which at least one side wall of one of the rafters is conical.