NL192044C - Suction head for a dredger. - Google Patents

Description

1 192044

Suction head for a dredger

The present invention relates to a suction head for a dredging vessel, comprising a connecting part to which a suction line is connected for discharging dredging sludge, which connecting part 5 is provided on one side with means for hingedly attaching the suction head to a movable arm of the dredging vessel, which suction head, which is substantially symmetrical with respect to a vertical central plane, which extends in the mounted state in the extension of the arm, is intended to perform a reciprocating swinging movement with the arm, which perpendicular to this central plane, the connecting part on the other side of which is provided with a housing part, which contains a central suction chamber, into which the suction pipe opens, which suction chamber is bounded on either side of the central plane by an inlet cap, each of which is in the direction of movement seen from the suction head, the front end is open and communicates via an inlet opening the suction chamber, which suction chamber furthermore comprises a diverter valve for closing the rear inlet opening, always viewed in the direction of movement of the suction head, and comprising a transport screw for loosening and entraining the dredging sludge. Such a device is known from United States patent 4,146,982.

In the known suction head, a single transport screw is arranged in the suction chamber, which is open at the bottom, the screw being reversed in the middle direction, so that the material is fed from both ends of the screw to the center thereof. The diverter valve is formed by a cap extending over the entire length of the screw conveyor and this partially radially encircling cap. The inlet hoods present on either side of the suction chamber and thus of the screw are in open communication with the suction chamber over its entire length, one of these open connections being able to be closed by the said shuttle valve. In this known suction head, there are thus inlet caps on either side of the screw, which contain valves to prevent the suction of excess water and grids to prevent obstacles, such as stones or pieces of wood. These inlet hoods, grids and valves come into contact with the material to be dredged before it comes into contact with the screw conveyor. The obstacles can remain in front of the grid for a complete swinging movement, which in addition to clogging also cause additional clouding of the water.

The object of the invention is now to provide a suction head of the type indicated above, for dredging highly polluted dredging sludge, wherein during dredging it is necessary to prevent a great turbulence in the water and the sludge from spreading in the water, and settled again elsewhere. Subsequently, care must be taken not to carry too much water with the dredging sludge. With contaminated sludge, this water cannot simply be returned, and entraining too much water has an adverse effect on the efficiency of the dredging process. This means that the current strict environmental regulations can be met.

This object is achieved according to the invention by means of a suction head, the inlet hoods on either side of the suction chamber of which are designed as screw cabinets, in each of which one. conveyor screw is mounted, the rotation axes of the two conveyor screws lie in a common horizontal plane, and the mutual distance between the rotational axes of the two conveyor screws towards the connecting part decreases, so that the housing part has the shape 40 in top view of an isosceles trapezoid and its conveyor screws are disposed along its bevels, the suction chamber being located in the area where the conveyor screws are closest to each other and the shuttle valve being formed by a flat plate pivotable about a center plane axis, which axis is perpendicular to the plane formed by the rotation axes of the screw conveyors, and is located near the point where the screw boxes are closest to each other. This arrangement has the advantage that with every swinging movement a transport screw always lies on the outside of the suction head and thus comes into contact first with the material to be dredged. In this way, the material to be dredged cannot therefore be turned over by blockages which disturb the flow always present before the screw. Because the two screws run diagonally towards each other in the transport direction, the swinging movement supports the transport of the dredged material to the suction chamber. Finally, this arrangement allows the use of a diverter valve, which is designed as a flat plate and is therefore inexpensive to manufacture, easy to operate and does not impede any discharge of the dredged material. It is noted that Japanese patent application 61286421 discloses a suction head for a dredging device with a connecting part comprising a central suction chamber, to which a suction line is connected for the discharge of the dredging sludge, which suction head, which is intended for a reciprocating 55 reshaping swinging movement substantially perpendicular to a central central plane, symmetrical to the vertical central central plane, with inlet caps on each side of the suction chamber fitted in each of which has a transport screw 192044, the rotary axes of which are in a lie horizontally in a horizontal plane. This known suction head, whose transport screws on the periphery are provided with cutting edges, which are able to cut hard soil, does not contain a valve system to prevent the dredged material dredged in one regard from escaping on the other side of the suction chamber and also has no width of the suction chamber decreasing towards the extraction site, as a result of which the loosened material cannot be efficiently pushed to the extraction location.

A dredging implement with two conveyor screws arranged in a common plane is also known from US patent 5,148,615. The two screws each have a separate screw box, the sides of the screws not covered by the screw boxes facing each other. In this known device, the material conveyed by the screws is pushed, over an area of gradually decreasing width, to the suction chamber with suction device, which is located close to the smallest distance between the screw conveyors. In addition to the fact that this known suction head cannot operate with a reciprocating pivoting movement, there is no closed suction chamber with diverter valve, which is connected via a passage to each of the screw boxes. As a result, the detached material will spread through the water.

According to the invention, the housing part is formed by a trapezoidal top plate with an equally large parallel bottom plate, and the screw boxes each consist of one half of a circle cylinder divided along the diameter, which are mounted in the housing in such a way that the two longitudinal edges thereof almost coincide with the sloping side edges of resp. the top and bottom plate, and on the top plate 20 of the housing part, an adjustable cap is arranged along each of the sloping sides, which extends over the entire length of the screw and the part of the circumference of the relevant transport screw protruding outside the box can cover more or less. This embodiment offers the possibility of covering the screw more or less if the thickness of the sludge layer to be removed is smaller than the diameter of the screw concerned, so that unnecessary much water is not sucked in and the spread of the loosened sludge is prevented in the water.

The invention is further elucidated with reference to the annexed drawing, which shows an exemplary embodiment of the suction head according to the invention, and in which: figure 1 is a schematic perspective view of a dredger with a suction head 30 according to the invention; Figure 2 shows a side view of the suction head in Figure 1, with the transport screw omitted for clarity; figure 3 shows a section according to the line III-III in figure 2, in which only one of the two transport screws is shown in detail; Figure 4 shows a section according to the line IV-IV in figure 3; figure 5 is a section according to the line V-V in figure 3; figure 6 is a section according to the line VI-VI in figure 3; figure 7 shows on a larger scale a partial cross-section corresponding to figures 5 and 6 of an embodiment of the suction head, which is provided with an adjustable cap; and Figure 8 is a partial plan view of the hood of Figure 7.

Figure 1 shows a dredging vessel 1, which is provided with a dredging arm 2, which is hingedly connected to the dredging vessel in a vertical plane. At the free end of this arm a suction head, which is indicated in its entirety by reference numeral 3, is attached. A suction pipe 4 runs from the dredger vessel 1 over the arm 2 and is connected to the suction head 3 by suitable means. The arm 2 can be moved up or down in the usual manner by means of a hoisting member 5, while the vessel 1 with the arm 2 can make a pivotal movement around the stern thereof using anchor cables 6. By means of this pivoting movement, the suction head is moved over the bottom to be dredged, as shown, for example, by the arrow A. The suction head 3 is moreover rotatably connected to the dredging arm 2 about a horizontal pivot axis 7, whereby the position of the suction head can be adjusted. adjusted by means of two piston-cylinder assemblies arranged between the suction head 3 and the arm 2. The part of the suction line 4 adjoining the suction head 3 is flexible, so that it can follow the rotation of the suction head about the axis 7.

As can be seen from figure 2, the suction head 3 according to the invention consists of a connecting part 9, with which the suction head 55 is hinged to the dredging arm 2 and a cutting part 10. The connecting part 9 contains the horizontal hinge shaft 7, around which the suction head can pivot relative to of the dredging arm, while the piston-cylinder assemblies 8 are hingedly connected on the one hand to coupling plates 12 arranged on the top of the connecting piece 192044 part, and on the other hand are hingedly connected to the arm 2. The connecting part also comprises a tube piece 13, on which the suction line 4 can be connected.

The cutting part 10 of the suction head consists of a top view formed as an isosceles trapezium, which protrudes like a nose on the side of the connecting part 9 facing away from the arm 2. As can be seen from Figures 3-6, the trapezoidal housing is voided by a top plate 14 running parallel to the horizontal pivot axis 7 and a bottom plate 15 which is parallel to it and runs at a distance below substantially the same size. The plates 14 and 15 are connected at the end remote from the connecting part 9 by a head plate 16 and the oblique sides of the trapezoidal housing by inwardly round curved plates 17, 18. The plates 17 and 18 are each formed as one half of the diametrically divided circle cylinder and connect with their longitudinal edges to the oblique sides of the top plate respectively 14 and the bottom plate 15. These plates thus each form an outwardly open screw-box, each of which has a transport screw 19 and 20, respectively. Enclose 20 at an angle of 180 °. Both screws are mounted on the one hand in the connecting part 9 and on the other hand in the head plate 16 of the cutting part 10.

The transport screws 19, 20 lie in a common plane, which extends parallel to the horizontal pivot axis 7, symmetrically on either side of a vertical central plane 21, in which plane the axis of the arm 2 is located. The mutual distance between the two transport screws decreases towards the end of the suction head remote from the arm 2 (see figure 3). The two screws preferably enclose an angle of approximately 20 °.

The conveyor screws are rotatably driven by drive means 22, such that the material to be dredged is fed to the end of the suction head remote from the dredging arm, that is to say in figure 3 from left to right.

The plates 17, 18 forming the screw cabinets each have an opening 23, 24, which is located near the rear end viewed in the direction of transport of the screws. Via these openings, each screw box communicates with a common suction chamber 25 located between the two screw boxes, in which suction chamber also opens the pipe section 13. The pipe section 13 runs from a connecting flange 13 'for the suction pipe 4 between the two screw boxes, the axis of the pipe section being located in the vertical symmetry plane 21. The pipe section 13 hereby changes from a round cross section at 13 "to a rectangular cross section (see figures 5 and 6), with which the pipe section then opens into the suction chamber 25 with the mouth 13" '.

Subsequently, a diverter valve 26 is provided in the suction chamber 25, which has a valve body 27 designed as a rectangular flat plate. The valve body 27 connects with the vertical end edge to the left of figure 3 to the rectangular mouth 13 '"of the pipe piece 13, while the valve body with the opposite vertical end edge is fixedly connected to a vertical shaft 28 rotatable in the trapezoidal housing, of which the centreline also lies in the vertical symmetry plane 21. The shaft 28 protrudes at the top 35 through the top plate 15 of the trapezoidal housing and is there fixedly connected to one end of a lever 29, the other end of which is hinged to a piston cylinder assembly 30. With the aid of this piston cylinder assembly 30, the shaft 28 with the valve body 27 connected thereto can be rotated.

As seen in figure 3, the mouth 13 '' of the pipe section 13 has a curvature in plan view, the center of curvature of which coincides with the axis of the shaft 28. In this way, the vertical end edge of the valve body always connects to the mouth 13 "". In the position of the valve body 27 shown in Figure 3, the vertical end edge of the valve body connects to the vertical side edge of the mouth 13 "" in top 3 in Figure 3, and the connection between the mouth 13 "" of the pipe section 13 and the screw 20 is interrupted via the opening 23, while the passage of the screw 19 to the mouth 13 '"of the pipe piece 13 is open. When the valve body 27 is turned in the direction of the arrow B, until the vertical end edge connects to In the bottom vertical side wall of the mouth 13 "" in Figure 3, the screw 20 communicates with the mouth 13 "" through the opening 24, while the connection between the screw 19 and the mouth 13 "" is closed. Thus, by adjusting the diverter valve 26, the screw 19 or the screw 20 can optionally be connected to the suction line 4.

Finally, figures 7 and 8 show an embodiment of the invention, in which an adjustable elongated cap 32 is arranged on the top plate 14 of the cutting part 10 along both sloping sides thereof. The adjustable hood consists of a bent plate 33, which extends over almost the entire length of the bevel. The bent plate 33 is provided at both ends with a perpendicular end plate 34. Via these end plates 34 the hood is rotatably mounted near the one longitudinal side edge 55 about an axis 35, which is again mounted between partitions 36 arranged perpendicular to the top plate 14. .

A stiffening tube 37 is welded along the opposite longitudinal side edge of the plate 33, which also connects the end plates 34 to each other.

Claims (2)

192044 4 Figures 7 and 8 show only one end of the adjustable hood, which will explain how to adjust the hood, bearing in mind that the other end of the hood is designed in the same way . A borehole 38 is provided in the end plate 34, which can be in contact with a number of boreholes 39, which are arranged at an equal radial distance from the shaft 35 in the baffle 36. By inserting a locking pin (not shown) through mutually matching holes 38 and 39, the hood can be fixed in the desired position. The operation of the device according to the invention will be explained below. In the position shown in figure 1, the suction head makes a pivoting movement in the direction of arrow A. This means that the screw 20 not visible in this figure is driven and the screw 19 is inoperative. The diverter valve 26 is in the position in which the opening 23 is closed and the opening 24 provides a connection from the screw 20 to the suction pipe 4. When the suction head has reached the end of this stroke, the dredger is slightly displaced and a pivoting movement is then performed against the direction of the arrow A, wherein the screw 19 is active and the diverter valve assumes the position shown in figure 3. Due to the symmetrical arrangement of the two screws relative to the vertical symmetrical surface 21, continuous operation is thus possible. The adjustable cap 32 offers the possibility to enclose the screw at an angle of more than 180 °, so that it is also possible to remove a layer of sludge, the thickness of which is less than the diameter of the screw, without passing through the part of the screw projecting above the sludge layer, water is sucked in. Since only water is sucked in between the bottom of the cap and the top of the sludge layer, the danger of the sludge spreading in the water and causing cloudiness is also avoided. By changing the position of the suction head with the aid of the piston-cylinder assemblies 8, it can be used in the same way when dredging an inclined bottom. 25 Conclusions Suction head for a dredging vessel, comprising a connecting part to which a suction pipe is connected for discharging dredging sludge, which connecting part is provided on one side with means for hingedly attaching the suction head to a movable arm of the dredging vessel, which suction head, which 30 is substantially symmetrical with respect to a vertical central plane, which in mounted condition extends in the extension of the arm, is intended to perform a reciprocating swinging movement with the arm, which is substantially perpendicular to this central plane which connecting part is provided on the other side with a housing part, which contains a central suction chamber, into which the suction line opens, which suction chamber is bounded on either side of the central plane by an inlet cap, each of which is seen in the direction of movement of the suction head the front side is open and communicates with the suction chamber via an inlet opening, which suction chamber is furthermore a wipe selector valve comprising for closing the rear inlet opening, always viewed in the direction of movement of the suction head, and comprising a screw conveyor for loosening and entraining the dredging sludge, characterized in that the inlet hoods located on either side of the suction chamber (25) are designed as screw cabinets (17, 18), in each 40 of which a transport screw (19, 20) is mounted, with the rotational axes of the two transport screws in a common horizontal plane, and the mutual distance between the rotational axes of the two transport screws the direction away from the connecting part becomes smaller, so that the housing part (10) has an isosceles trapezoid in plan view and the transport screws are arranged along the sloping sides thereof, the suction chamber being located in the area where the transport screws 45 are closest to are located one another, and the shuttle valve (26) is formed by a flat plate (27) which is pivotable about a in the center plane (21) axis (28), which axis is perpendicular to the plane formed by the rotation axes of the conveyor screws, and is located near the point where the screw boxes are closest to each other. Suction head according to claim 1, characterized in that the housing part is formed by a trapezoidal top plate (14) with an equal parallel bottom plate (15), and the screw cabinets each consist of one half of one along the center line divided circular cylinder, which are mounted in the housing such that the two longitudinal edges thereof coincide substantially with the oblique side edges of resp. 5 192044 top and bottom plate, and on the top plate (14) of the housing part an adjustable cap (32) is provided on each of the sloping sides, which extends over the entire length of the screw and the part protruding outside the box of the circumference of the respective screw conveyor can cover more or less. Hereby 4 sheets drawing