NL1016035C2 - Device for providing a slot in the bottom of a water area. - Google Patents

Description

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Title: Device for making a slot in the bottom of a water area.

The invention relates to a device for providing a trench in the bottom of a water area, in particular for accommodating a pipeline or cable in the bottom, comprising a vehicle or the like to be displaced under water with respect to said bottom under water. on which are arranged at least one or more spray arms 10 extending downstream of the pipeline or cable and provided with spray nozzles for high-pressure water jets.

Such a device is known from US-A-4112695. Two vertically adjustable spray arms are provided in this device on which rows of spray nozzles are provided.

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When using this device, the soil in the soil is fluidized by jets of water coming out of the spray nozzles. The spray nozzles are inclined such that the water jets are directed both forwardly and inwardly in the downward direction. With such an embodiment of spray arms and spray nozzles 20 problems can arise when loosening soil with a certain cohesion, such as clay. This means that the soil is insufficiently cut and cannot be drained sufficiently.

The object of the invention is to avoid this drawback and to provide a device with which a trench can be provided in types of soil of mutually different cohesion, such as clay, sand and the like. To this end, the device is characterized in that means are provided for moving the spray arms back and forth in a successive manner during operation.

As a result of the back-and-forth stroke that the emerging water jets exert on the surrounding soil, this soil is also efficiently cut and sprayed, even with its strong cohesion. The spray arms can herein perform a reciprocating stroke in the longitudinal direction or a reciprocating stroke in the circumferential direction under the influence of the movement means.

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In addition, it is possible for the spray arms to perform a lateral reciprocal stroke or a lateral reciprocal stroke in the vertical plane, i.e. transversely of the direction of travel.

In an advantageous embodiment, at least a pair of such spray arms are provided side by side to operate on either side of the pipeline or cable.

In a further embodiment, the spray nozzles are arranged on a spray arm divided in longitudinal direction and circumferential direction into mutually equal groups such that the water jets from such a group exit in different directions. The soil in the immediate vicinity is therefore simultaneously exposed and cut up to these water jets in different directions. By making the distance of the reciprocating stroke in the longitudinal direction preferably equal to the distance in each case between two groups, an efficient cutting of the soil is obtained. In this embodiment with such a dimensioning, it is possible to work with fewer water jets and therefore spray nozzles.

Here, each group comprises at least one spray nozzle for spraying a water jet substantially forwards in the direction of movement of the vehicle and / or each group may comprise two spray nozzles to substantially two water jets, respectively inwards and obliquely outwards, in the direction of movement of the vehicle. mutual angle of, for example, 30 degrees.

Furthermore, each group can comprise two spray nozzles for spraying two water jets, both diagonally inwards and diagonally outwards, substantially in the direction of movement of the vehicle.

In order to even better cut the soil to be removed in the transverse direction, it is advantageous for the groups to be provided with further spray nozzles for spraying water in a direction substantially transverse to the direction of movement of the vehicle, such as in the direction of an adjacent spray arm. , for example, to cut and spray a residual back of soil under the pipeline or cable.

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The purpose of the above embodiments is to obtain sufficient coverage and to remove the soil near the spray arm from the reciprocating stroke of the spray arms with a group configuration of spray nozzles, which can vary from a simple to more complex shape. to spray.

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In this context, a spray nozzle is to be understood to mean a water outlet opening, two or more of which, if necessary, having the same or different discharge direction can be accommodated in a combined spray nozzle.

In order, in particular, to be able to effectively cut and remove the ground under a pipeline or cable to be laid, it is possible that one or more of the spray arms are L-shaped and are formed by a substantially vertical long spray arm which is provided at the end of a substantially horizontal short spray arm provided with spray nozzles. It is also possible that one or more of the spray arms are h-15 shaped and are formed by a substantially vertical long arm and a shorter arm connected thereto by means of a connecting spray arm. In these embodiments, each of the short spray arms can moreover be rotated from an inactive position located outside the pipeline or cable to an active position below the body of the pipeline or cable to be buried.

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The vehicle can consist of a ship-guided carriage, a caterpillar vehicle or a vehicle with its own propulsion, and can be movable both above and over the bottom or on the pipeline itself. 1 30

By adding buoyancy to the vehicle and thus reducing the friction, the required pulling force can be reduced. Of course, the device can advantageously also be used for loosening sand and such material.

The invention will now be explained in more detail with reference to the figures.

Figure 1 shows a view of a device according to the invention guided by a ship over the seabed during the introduction of a pipeline or cable into the bottom.

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Figure 2 shows a schematic view of the device in side view.

Figure 3 shows a schematic view of the device in front view.

Figure 4 shows a schematic view of the device in top view.

Figure 5 shows a section along the line V-V in Figure 4.

Figure 6 shows a section along the line VI-VI in Figure 4.

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Figures 7a and 7b show a top and side view, respectively, of a spray arm with possible spray directions.

Figure 8 is a view of two spray arms which are provided with further spray nozzles for spraying water in substantially horizontal direction.

Figures 9a, 9b and 9c show different forms of compensation of reaction forces.

Figure 10a shows the front view of an embodiment of L-shaped spray arms in the active position with indicated lateral reciprocation.

Figure 10b shows the front view of an embodiment of L-shaped spray arms in the active position with indicated lateral reciprocating stroke.

Figure 11 shows the front view of an embodiment of h-shaped spray arms in the active position, with indicated reciprocating stroke in the longitudinal direction of the spray arm.

The schematic drawing of figure 1 shows a slide which is pulled or guided by a ship 2 over the seabed by means of a cable 3, wherein a trench 4 is provided in the seabed, for example made of clay, into which a pipeline or cable 5 is buried.

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The carriage 1 carries a frame 6. Viewed in the normal direction of movement of the carriage, the frame carries two spray arms 7, 8 and two suction arms 9 arranged behind the spray arms and known per se. Means (not shown) are present (for example, hydraulic cylinders) ) to move both the spray arms and the suction arms from the position shown in solid lines in figures 2 and 3, the lower end of the arms being at or just above the seabed, to a dotted lines in figures 2 and 3 indicated working position and back. In addition, means 11 are provided for causing the spray arms 7 and 8 to perform a reciprocating stroke movement in an operating position. This reciprocating movement of the spray arm can be a stroke in the longitudinal direction, i.e. along the longitudinal axis, or a rotational stroke in the circumferential direction, i.e. around the longitudinal axis. In addition, the reciprocating movement can be a lateral horizontal stroke or a rotational stroke in the vertical plane from a point or point of rotation at the means 11. Combinations of back and forth movements, such as a back and forth movement in the longitudinal direction with a rotation stroke in the circumferential direction, are also possible.

The spray arms 7 and 8 are connected to a high-pressure water pump (not shown) to produce water with a pressure of, for example, 10 to 100 bar. The spray nozzles 12 have a diameter of, for example, 1 to 15 mm.

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The Z-shaped suction arms 9, 10 are rotatable about the axis of the vertical body through an angle of approximately 45 ° (see figure 4). Means, not shown, are present to cause this rotation. These suction arms are mainly used when digging pipelines in sand.

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The suction arms 9, 10 are connected to a centrifugal, venturi or airlift pump. The drive of the venturi pump can optionally take place by means of the high-pressure water generated by the high-pressure pump. The discharge mouth of the suction arms (see Figure 5) is, for example, about 3 meters above the seabed. It is also possible to move the discharge point further away by extending the discharge pipe upwards or to the side. At start-up (see figures 3 and 4) the suction arms 9 and 10 are in a position indicated by dotted lines in figure 4, wherein the inlet piece and -, ·.

101 & 6 extend the outlet piece parallel to the direction of movement of the carriage 1 indicated by arrows.

When water under high pressure passes through the spray nozzles 12 of the spray arms 7, 8 and the spray arms are loaded downwards, for example by hydraulic means, the spray arms will sink into the ground and form a hole. The suction arms 9, 10 are also lowered and rotated into the position along the solid lines in Figures 4 and 5.

When the carriage 1 is advanced and the spray arms are moved back and forth by means 11, the clay soil will be cut and sprayed and can easily be sucked up by the suction arms. As indicated by an arrow in Figures 4 and 5, the soil is deposited laterally from the carriage on the seabed.

Each of the spray arms 7 and 8 is provided with groups of spray nozzles 12. In each group there is at least one spray nozzle with an outlet direction straight ahead, and / or two spray nozzles with exit directions ahead and sideways. Furthermore, two spray nozzles may be provided per group with discharge directions obliquely downwardly and sideways. The pattern of high-pressure water jets is apparent from Figures 7a and 7b, in which a top and side view of a spray arm, respectively, is given.

A spray nozzle is shown for each position in the figures. It will be understood that by the above described spray nozzles it is meant that are either integrated into a spray nozzle screwed into the spray arm or screwed separately into and next to and / or directly above each other in the spray arm.

Figure 8 shows two spray arms 7, 8 placed next to each other and which are provided with spray nozzles 12. The spray arms moreover comprise further spray nozzles 13 for spraying water substantially in the lateral direction. The spray nozzles 13 are arranged such that the water from the spray nozzles 13 is directed at an adjacent spray arm and preferably in mutually staggered manner from the water jets directed towards each other. That means 1 '- - 7 that two spray arms directed next to each other can jointly effectively destroy the soil between the spray arms.

As a result of the water jets emitted by the spray nozzles under different discharge directions, both horizontally and at angles therewith, reaction forces will be exerted on the vehicle in directions opposite the said discharge directions. In order to prevent the vehicle from moving laterally or upwards during operation, thrusters are generally arranged on the top and / or the sides of the vehicle in order to substantially compensate these reaction forces. In order to avoid this use of the thrusters, in the present embodiments further spray nozzles can be provided in the spray arms, the discharge directions of which are substantially opposite to those of the spray nozzles mentioned.

For example, additional spray nozzles 14 may be provided on a spray arm, the exit directions of which are mirrored with respect to the horizontal plane to those of the spray nozzles which are directed obliquely sideways and / or downwardly, as shown in Fig. 9a. Thus, as compensation for the forward-facing spray nozzles, one or more rear-facing spray nozzles 15 can also be provided, as shown in Figure 9b. As a result of this compensation, not only are the forces required for the thrusters smaller or superfluous, but the forces and powers with which the spray arms are rotated and moved successively are greatly reduced or reduced to zero.

Figure 9c shows the spray nozzles 13, as described in figure 8, wherein these spray nozzles can be mounted rotated backwards on the spray arms 7, 8, so that a reaction component is produced in the direction of movement.

The spray arms 7 and 8 can be designed as an L-shaped body, as shown in figure 10. Such an L-shaped spray arm is made up of a substantially vertical, long spray section and a rotatable, substantially horizontal, between inactive and active position. spray section. The vertical, long spray arm 16 is connected to the horizontal spray arm 18, and the vertical, long spray arm 17 is 8 connected to the spray arm 19. Each of the horizontal and, if necessary, of the vertical arms is provided with spray nozzles 12 and possibly also nozzles 13.

In a variant, the vertical, long spray arms 16, 17 are rotatable about their axis about an angle 5 of at most 90 ° in the active position, as is shown in front view in Figure 10.

The reciprocating stroke at the L-shaped spray arms can be a lateral horizontal movement in a vertical plane from a point at the means 11, such that the horizontal arm performs a short horizontal stroke along its longitudinal axis. This is shown in Figure 10a. In addition, the back-and-forth stroke can be one. are lateral rotation stroke, in a vertical plane comprising the L-shape, from a point of rotation at the means 11, such that the horizontal arm performs a short stroke in the lateral direction. This back-and-forth stroke is indicated in Figure 10b.

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It is also possible that the spray arms are embodied as an h-shaped body shown in Figure 11. Such an h-shaped spray arm consists of a vertical, long arm and a shorter vertical arm extending from it, which can be rotated between an inactive and active position.

The vertical, long spray arm 20 is connected to the spaced-apart shorter vertical spray arm 22 by means of the substantially horizontal connecting spray arm 24. In this way also the vertical, long arm 21 is connected to the shorter vertical spray arm 23 by means of connecting spray arm. 25. Each of the shorter spray arms, connecting spray arms and, if necessary, long vertical arms is provided with spray nozzles 12 and possibly also nozzles 13.

In a variant, the vertical, long spray arms 20, 21 are arranged rotatably around its axis through an angle of at most 90 ° in the active position, as shown in Figure 11 in front view.

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As shown in Figure 11, the reciprocating stroke at the h-shaped spray arms may be the vertical movement in the longitudinal direction of the spray arms.

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In the possible L-shaped and H-shaped embodiments, the spray nozzles are arranged on the spray arms in such a way that they are directed substantially forward in the said active position.

In the L- or h-shaped spray arm according to Figs. 10 or 11, the short arm is rigidly attached to a long arm that is rotatable about its longitudinal axis or the short arm is attached to a non-rotatable long arm and is separately rotatable. In both variants the short arm can then be rotated from an inactive position outside the pipeline or cable to an active working position under the pipeline or cable. In the embodiments with these L-shaped or h-shaped spray arms, they are often preceded in the forward direction by a single, vertical spray arm paving the way.

The device according to the invention is intended in particular for soil types with cohesion, such as clay, but can also be used in soil with less cohesion, for example sand, silt and the like.

It goes without saying that further variants are possible within the scope of the invention. For example, many arrangements of h-shaped and / or L-shaped spray arms are possible and the h-shaped spray arms can additionally be provided with at least one additional, shorter, vertical spray arm. The L-shaped spray arms can also be additionally provided with at least one additional horizontal spray arm.

With the aid of the device according to the invention, for example, 500 to 2000 meters of pipeline with a diameter of approximately 1 meter in clay soil with a cohesion resp. from 100 to 20 kN / m2. The device can be used at water depths between 5 and 3000 meters and for a pipe diameter of 200-1300 mm. Corresponding or greater speeds can be achieved in sandy soil. Also when laying cables, which generally have a smaller diameter, such speeds can be achieved.

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Claims (19)

1. Device for providing a trench in the bottom of a water area, in particular for accommodating a pipeline or cable in the bottom, comprising a vehicle or the like that is displaceable relative to said bottom under water, on which are arranged at least one or more spray arms extending downwardly next to the pipeline or cable, provided with spray nozzles for high-pressure water jets, characterized in that means are provided for moving the spray arms back and forth in operation during operation. Device as claimed in claim 1, characterized in that at least a pair of such spray arms are provided next to each other in order to act on either side of the pipeline or cable, respectively. Device as claimed in claim 1 or 2, characterized in that the said moving means cause the spray arms to perform a reciprocating stroke in the longitudinal direction. 4. Device as claimed in claim 1 or 2, characterized in that said moving means cause the spray arms to perform a lateral reciprocation in a vertical plane. 5. Device as claimed in claim 1 or 2, characterized in that the said moving means cause the spray arms to perform a lateral reciprocating stroke in a vertical plane. Device as claimed in claim 1 or 2, characterized in that the said moving means cause the spray arms to perform a reciprocating rotation in the circumferential direction. 30 Device as claimed in claims 3 to 6, characterized in that said movement means cause the spray arms to perform a combination of reciprocating movements. 10160 ^: S 8. Device as claimed in any of the claims 1 to 7, characterized in that the spray nozzles are arranged on a spray arm distributed in the longitudinal direction and / or circumferential direction such that the high pressure jets exit in different directions. Device as claimed in claim 8, characterized in that the spray nozzles are arranged on a spray arm divided into equal groups along the longitudinal direction. Device as claimed in claim 9, characterized in that the reciprocating stroke of said moving means of the spray arms is substantially equal to the distance in each case between the groups of spray nozzles. 11. Device as claimed in claim 9 or 10, characterized in that each group of spray nozzles comprises at least one spray nozzle for spraying a water jet substantially forwards in the direction of travel of the vehicle. 12. Device as claimed in claim 9 or 10, characterized in that each group of spray nozzles comprises two spray nozzles for spraying two water jets substantially inwardly and obliquely outwardly in the direction of movement of the vehicle. 13. Device as claimed in claim 9 or 10, characterized in that each group of spray nozzles comprises two spray nozzles for spraying two water jets obliquely downwardly and obliquely outwardly, respectively, substantially in the direction of movement of the vehicle. 14. Device as claimed in claim 11, 12 or 11, characterized in that each group of spray nozzles also comprises a spray nozzle for spraying a water jet substantially transversely of the direction of travel of the vehicle. Device as claimed in any of the foregoing claims, provided on the spray arm (s) of the said spray nozzles, characterized in that further '1' spray nozzles are provided on the spray arms, the discharge directions of which - for the purpose of compensating reaction forces - are substantially are opposite to those of said spray nozzles. Device as claimed in any of the foregoing claims, characterized in that at least one spray arm consists of two or more sub-arms extending mutually at an angle or at a distance. 17. Device as claimed in claim 16, characterized in that the at least one spray arm has substantially an L-shape with a vertical, long arm and a horizontal, short arm. Device as claimed in claim 16, characterized in that the at least one spray arm has substantially an H-shape with a vertical, long arm and a shorter arm extending at a distance therefrom. 15 Device as claimed in any of the claims 16, 17 and 18, characterized in that the short arm can be rotated from an inactive position located outside the pipeline or cable to an active working position below the pipeline or cable. r