NO147726B - CONCRETE ANCHORING FOR ROOMS, WIRES, CABLES M.M. - Google Patents

Description

The present invention relates to a concrete anchorage for pipes, wires, cables and the like of the type specified in the introduction of the attached claim 1.

The invention is primarily applicable to

laying pipes, wires, cables and the like in water, but it is understood that the anchoring can just as well be used for laying on the ground, especially when placing the pipe lying freely on the ground.

When laying pipes, wires, cables and the like, in order to keep the pipe in place, this can be blocked by means of weights that are clamped around the pipe.

For the sake of simplicity, the invention will only be described below with regard to laying pipes in water, but it is obvious to the person skilled in the art that this does not constitute any limitation of the invention.

A previously known type of weight or anchorage for

pipe consists of two plates made of concrete with a cross on it

the plate's planar continuous semi-cylindrical groove in each plate shark part.

For mounting the anchoring halves on the pipe, through bolts are used. However, this known type of concrete anchoring has the disadvantage that the bolts corrode, so that the anchoring halves eventually loosen from each other and the pipe in unfavorable cases loosens from its anchoring. Furthermore, with this known type of anchoring, the pipes will be placed relatively close to the bottom of the anchoring, and when this sinks into the seabed, at least certain parts of the pipe will rest directly against the bottom, and if this is rocky, the pipe can be damaged.

To solve the problem of corroding joint bolts is

a modified type of anchoring has been proposed, which likewise consists of two concrete halves, but where the joining takes place by means of clamp-shaped concrete elements that are pressed into grooves in the sides of the concrete halves. Alternatively, the anchoring is made as a block with a U-shaped groove, where the locking takes place by pressing a complementary piece into the U-shaped groove on top of the pipe. In both of these cases, great force is required to join the anchoring parts, and usually you have to use special machines for the joining.

All of the anchorages mentioned above are symmetrical, and especially when laying pipes in water, the pipe with the anchorage can turn during laying, so that some anchorages can come to rest on one of its corners, and the pipe can in such a case come to move, which could damage the pipe.

The invention aims to eliminate the disadvantages of the previously known anchorages and to provide a concrete anchorage for pipes, wires, cables and the like, which can be easily handled and clamped onto the pipe without the use of special pressing tools, which has no corroding metal parts, which is designed in such a way that under normal conditions it always arrives in the correct position on the seabed, and which is produced in any length, depending on the anchoring force desired.

This is achieved according to the invention by an anchoring which exhibits the features specified in attached claim 1. Further advantageous features of the invention are specified in

the independent claims.

The invention will now be described in more detail with reference to the drawings. However, it is understood that the embodiments of the invention described and shown in the drawings only constitute illustrative examples, and that many different modifications may occur within the scope of the claims.

In the drawings, fig. 1 in perspective a concrete anchorage according to the invention, without pipes mounted in it. Fig. 2 is a section along the line II - II in fig. 1, but with the anchorage mounted on a pipe. Fig. 3 is an alternative embodiment background of an anchorage according to the invention, seen in the axial direction of the pipe. Fig. 4 shows, in the case of a broken piece, the method for installing the anchorage on a pipe. Fig. 5 shows a detail of the anchoring according to the invention, seen in cross-section. Fig. 6 shows the anchoring in fig. 1 and 2, seen from above. Fig. 7 and 8 show alternative embodiments of a tension band for mounting the anchorage on the pipe, and

fig. 9 shows an embodiment of a simple tool to facilitate the installation of the tension band.

The concrete anchorage according to the invention generally consists of an anchoring part 1, one or more construction straps 2 and one after several tension straps 3.

The anchoring part is designed as a generally T-shaped foundation 4 in cross-section, the length of which can be adjusted according to the anchoring force etc. as desired. In fig. 1 shows a foundation made as a two-module unit which is mirror-symmetric about its axial centreline. The foundation can therefore be made in the length of one, two or more modules.

The T-shaped foundation 4 is made with an upwardly open, channel-shaped groove 5 for a wire 6, a pipe, a cable or the like. The groove 5 has a slightly larger diameter than the calculated line 6 to enable the line to be installed on construction tape,

as in fig. 1 is shown fixed in the slot 5 at each end. The installation bands 2 have the purpose partly of forming a somewhat springy fixation of the anchorage on the wire, partly to prevent the wire from touching and possibly rubbing directly against the concrete, partly also to form an axial locking of the anchorage on the wire. For this purpose, the bands are designed with a number of radial ribs 7 running parallel to each other. The installation bands, which are preferably made of some other water-resistant elastomeric material, can be glued or otherwise fixed to the concrete. In fig. 4 shows how the installation bands with a radially outward facing bead 8 can be embedded in the concrete material.

The base 9 of the T-shaped foundation 4 forms a lower, massive part, which, due to its accumulation of mass, looks downwards, so that the line 6 is laid upwards as far as possible when the pipe is laid.

The upper part of the T-foundation 4 forms a holder 10 located on each side of the groove 5 for the tension bands 3. For this purpose, the T-upper part is designed with slots 11 running radially outwards from the groove 5 with a width that is somewhat greater than the width of the calculated tension band 3, and the slots extend from the outer edge of the anchoring part to the base 9. The tension band holders are thereby formed by the protruding projections 12 on each side of the slot 11. In the example shown, a pair of slots has been arranged for each module length of the anchoring part, but it is it is understood that two or more such slots can be arranged for each module length.

The tension band 3 is made of a water-resistant elastomeric material, and it has a length that is less than the distance between the projections 12 on each side of the anchoring part and across the wire, so that the tension band with elastic tension can be wrapped around the pipe. The tension band can have any suitable shape, and in fig. 7 shows such a form. In this case, the tensioning band is rectangular, and it is designed at each end with a thickening 13 for contact with the holder's projections 12. When installing the concrete anchor on rough cables, great forces may be required to wrap the band 3 around the cable, and in this case, one uses a tool as shown in fig. 5 and 9. The tool in this case consists of a two-armed fork 14 with a handle 15 and angled ends 16. The fork is designed to engage over the thickened part 13 by wrapping the tension band 3 around the wire 6 as shown in fig. 5. Alternatively, to facilitate the assembly of the tension band 3, two thickenings 13a and 13b can be arranged, whereby the fork 14 engages between these two thickenings and/or in a hole 17 in the outer thickening 13b.

When laying a pipe on a very stony bottom, despite the large mass accumulation of concrete under the center of the pipe, it can happen that the anchorage turns upside down, and in such a case to prevent the line 6 coming to rest directly against the bottom, can the anchorage is provided with upward projections 18, as shown in fig. 3. If the anchor should accidentally end up upside down, it will rest on these projections 18 and keep the cable above the bottom resting in the tension bands 3.

In fig. 1 shows the concrete anchorage according to the invention made with two tension band grooves 11 arranged symmetrically along the length of the anchorage. This forms two composite unit lengths in this way, but as mentioned earlier, it can be made with any suitable length. When laying pipes or lines of liquid material in water, e.g. pipes made of polyester material, it may be appropriate to dimension the anchorages so that the pipe floats as long as it is filled with air, but sinks when it is filled with that medium, e.g. water, which is to be transported through the pipe.

Claims (6)

1. Anchoring for pipes, wires, cables and the like, which must be anchored under water consisting of a cross-section in the essential T-shaped foundation of a concrete material, where the base (9) of the T-shaped foundation forms a massive anchoring part , and where the upper piece is designed with an upwardly open, trough-shaped groove (5) for the pipe (6) or the like and forms a protruding holder (10) on each side of the pipe groove (5) for one or more tension bands (3), with with the help the anchoring can be clamped onto the pipe (6) or the like, characterized in that the protruding holders (10) next to the pipe groove (5) are designed with one or more pairs of diametrically opposed open slots (11), which extend up to the base (9) of the foundation (4), and which on the underside forms a shoulder (12) for squatting the tension bands (3), and that the tension bands (3) are made of a rubber-elastic material and are designed at their ends with a thickening (13 ), which is greater than the width of the slots (11) for fixation of the tension bands on the underside (12) of these slots (11) . 2. Anchoring as specified in claim 1, characterized in that it has a length that is greater than the diameter of the track, and that it is designed with at least two pairs of mutually opposite slits (11) and associated tension bands (3). 3. Anchoring as stated in claim 1 or 2, characterized in that the tension bands (3) at one end are designed with two thickenings (13a, 13b), between which a tool (14) can intervene. 4. Anchoring as specified in one of the preceding claims, characterized in that the channel-shaped groove (5) has a larger diameter than the intended pipe, and that the groove at least at its ends carries construction bands (2) of an elastomeric material, on which the tube (6) rests. 5. Anchoring as specified in claim 4, characterized in that the anchoring bands (2) are designed with radial ribs. 6. Anchoring as stated in claim 4 or 5, characterized in that the construction straps (2) are glued to or embedded in the concrete material of the foundation (4).