DE1802158C3 - Method of suction dredging and suction dredging - Google Patents

Description

The invention relates to a method for suction dredging dredged material, as described in the preamble of Claim 1 is indicated. Such a method is known from FR-PS 14 67 425. Here it becomes The suction tube with the suction mouth located at its lower end is inserted into the bottom of the water and it a relatively large area of the sand soil around the suction mouth is fluidized by the suction dredging process. This fluidized dredged material works with the suction tube in the manner of communicating vessels, so that the through the lower suction mouth incoming suspension through the soil column in the suction pipe located above the suction mouth, except for about corresponding height is pushed up. The water inlet opening must be approximately at this level be held in order to ensure the desired mode of action, in which the sucked in proportionately heavy sand suspension by adding the water sucked in at the water inlet opening to the desired suspension concentration is brought. This adjustment of the height of the water inlet opening, what is achieved by opening a flap located in the relevant altitude is for Achieving the required concentration required , borrowed. If the water inlet opening is higher than the level of the sand column above the suction mouth, too much water is added and the result is a suspension that is too thin. However, if the water inlet opening is below the level of the sand column above the suction mouth, the heavy sand suspension sucked in from below escapes through the water inlet opening and prevents it the water entering, which means that too heavy a sand suspension is pumped upwards, which can lead to blockages in the pump and the lines and overall the suction process makes it uneconomical

The well-known system in which the water inlet opening is always approximately at the level of the above Suction mouth bearing soil column must therefore be kept has the disadvantage that the water inlet opening overall at a relatively large distance from the suction mouth inserted deep into the ground must be kept and that with strong sudden fluctuations in the depth of insertion, such as by Subsequent falls of the surrounding soil into the fluidized zone can occur, correspondingly large changes the distance between the suction mouth and the Water inlet opening are required. In the version with an in a tubular casing, which can be actuated by means of a hydraulic drive, requires this relative moderately large lengths of the sliding tube and the hydraulic actuation, which is because of the high production costs and the increased susceptibility to failure is disadvantageous The invention is based on the object predetermined optimal concentration of the upward to be able to adjust the conveyed suspension either without changing the distance between the water inlet opening and the suction mouth, or else while setting this distance at the same time if the suction mouth is deeply inserted into the ground with much smaller distances between the water inlet opening and suction mouth and a smaller one Stroke of the adjustment of the water inlet opening to get along, so that with shorter displacement distances can be worked.

The problem posed is achieved by what is stated in the characterizing part of claim 1 Characteristics.

Because, according to the invention, the water inlet opening is acted upon by pressurized water this water inlet opening is no longer at the level of the floor column above the suction mouth to be held, but can be placed closer to the suction mouth, although a The heavy sand suspension sucked in from below is reliably prevented from escaping into the water supply line. The 'setting on a The desired sand concentration can basically be achieved without changing the distance between the water inlet The opening and suction mouth are made by setting the pressure level of the pressurized water accordingly.

Although it is known from British Patent 8 37 669 a towing suction dredger in which the Soil material peeled off by a cutter in a • 65 immediately behind the cutter head Mixing chamber water is added to form a suspension, which is then passed out of the mixing chamber through the Suction tube is sucked up. The supply of the mixed water

takes place via a short pipe bend, which at its upper end with a in the direction of drag We} · the mouth opening is in connection with the surrounding water. The supply of the mixed water is thus carried out by pulling the dredger along the mouth of the elbow occurring dynamic pressure, which is only slightly greater than the pressure in the mixing chamber Even if there is too much sand in the lower end of the suction pipe, the pressure of the pressurized water can do not graze elevated and the sand is removed from the lower end of the suction pipe by the fact that one a flap on the back of the suction tube opens. A movability of the upper mouth of the The water supply line opposite the inlet opening of the cutting head is not provided for the rest.

The invention also relates to a suction dredger indicated in the preamble of claim 2 type Such a suction dredger is also known from the said FR-PS 14 67 425 is known the Asked _M object is achieved in such a suction dredger by the features specified in the characterizing part of Claim 2 Characteristics solved These control elements are primarily formed by the setting means of the pressurized water pump

According to a further embodiment of the invention is in the water supply line between the Pressurized water pump and the water inlet opening turned on the use of a water jet pump a water jet pump in the water supply line enables a high throughput of the Water supply and you get a large setting range with regard to the amount of water supplied.

Embodiments of a method and an apparatus according to the invention are given below described with reference to the drawing. In the drawing shows

F i g. 1 a schematic representation of a suction excavator while the method is being carried out,

F i g. 2 the lower end of a suction pipe of the suction excavator in a further embodiment and

3 shows a section along the line IH-III according to FIG. 2.

The suction dredger consists of a ship 10, a suction pump U, a suction pipe 12 connected to the suction side of the suction pump 11, a pressure pipe 13 connected to the pressure side of the suction pump 11 , a pressurized water pump 14, a water suction line 15 connected to the suction side of the pressurized water pump 14 and a The water supply line 16 connected to the pressure side of this pressurized water pump 14. The suction pipe 12 can be pivoted about a horizontal axis with respect to the suction pump 11. The pressurized water supply line Iu is connected to the pressurized water pump 14 via a flexible section 17.

The suction tube 12 terminates in an end portion 18 on which a sliding tube 20 telescopically displaceable by means of a hydraulic drive 21 and in the required shift position is adjustable on the end portion 18 rigidly attached one to the end portion 18 and the sliding tube 20 embracing jacket pipe 19 which is lower than the End of the end portion 18 protrudes. The water supply line 16 is connected to a jet nozzle 22 of a water jet pump 23, through which water is sucked in at a high throughput through inlet openings 24 and is pressed into the jacket tube 19. The end of the jacket tube 19, which is open at the bottom, forms a suction mouth 25 through which mainly fluidized dredged material enters.The pressurized water passes through the annular space between the sliding tube 20 and the jacket tube 19 to below the water inlet opening 26 of the sliding tube 20 and which is via the water inlet opening 26 of the sliding tube 20 Extending part 19a of the jacket tube 19 leads to the water inlet opening 26 to dredged material.

The procedure works as follows:

The end section 18 of the suction tube 12 is inserted deeply below the surface of the sand 27 and sand is sucked in. Near the end of the suction tube 12 within the area indicated by the dash-dotted line 28 , the sand is fluidized and behaves like floating sand. He then has the tendency to automatically rise into the end section 18 of the suction pipe 12 to the level of the sand standing above the suction mouth 25. As a result of the application of pressurized water to the jacket pipe 19, it depends on the overpressure of this pressurized water up to which level the sand rises in the jacket pipe 19 25 may occur, but not to the water inlet opening 26 of the Schieberchres 20 comes Then, the slide tube 20 on such a distance between suction port 25 and water inlet 26 is set to be at the respective pressure of the pressurized water from within the casing tube

19 enclosed ring channel and at the respective depth of the suction mouth 25 under the sand surface a sand-water suspension is sucked up, the sand concentration of which has the desired value

20 is sucked in, this can be corrected in that the sliding tube is extended further downwards or is retracted further upwards.

The stroke required for the sliding tube 20 is significantly smaller than in the event that no pressurized water is introduced into the jacket tube 19 . Almost over the entire length of the suction pipe 12 there is a suspension of the dredged material in the desired concentration between the water inlet opening 26 and the suction pump U, so that the suspension column hanging on the suction side of the sand pump is as light as possible while the heavier floating sand column outside the casing pipe 19 This light suspension column is pushed up via the suction mouth 25.

In the embodiment according to FIG. 2 and 3, a sliding tube 120 is inserted displaceably in the lower end section 118 of the suction tube 112 and can be displaced by a hydraulic drive 121 . A water jet pump 123 , which has a jet nozzle 122 and an inlet opening 124 , is switched into the water supply line 116. The jacket tube 119 is at the lower end to an apparent from Figure 3 the cross-section tapers Thereafter there are two opposing arc sections of the jacket tube 119 the sliding tube 120 immediately and two opposed channel portions 129 semi-circular cross section lead in the suction port 125 nozzle pipe sections 130, fixedly connected to the sliding tube 120 and are connected to c * em annular space between casing tube 119 and slide tube 120 or suction tube end section 118 . These nozzles formed in this way can, together with the water inlet opening 126 at the lower end of the sliding tube 120, via the

Suction mouth 125 can be extended in the manner shown in FIG. 2 while it is being introduced into the sand. The spray nozzles formed by the pipe sections 130 then protrude via the channels 129 and the suction mouth 125 and are fed by the water jet pump 123. This water jet pump 123 , corresponding to the water jet pump 23 , has the advantage that a high I can be achieved with its help during the introduction of the suction tube into the sand, so that the spray nozzles exert a powerful effect, while on the other hand the suction of sand is pumped in with the water particularly high throughput can be achieved by Wassi relatively low pressure

1 sheet of drawings

Claims (3)

Patent claims: 1. A method for suction dredging of dredged material through a suction pipe connected to a pump, which has a suction mouth at its lower end and a water inlet opening at a point between this and the pump at a distance from the suction mouth, wherein fluidized dredged material is sucked through the suction mouth and wherein the water supply into the water inlet opening is adjusted as a function of the column of fluidized dredged material located above the suction mouth and possibly other material stored on the dredged material in order to maintain a desired concentration of the dredged material in the sucked up dredged material-water mixture, characterized in that the water inlet opening (26 , 126) pressurized water is supplied with adjustable pressure and that the pressure of the pressurized water prevailing at the water inlet opening (26,126) is adjusted. 2. Suction excavator for performing the method according to claim 1, with one on a suction pump connected suction tube, which at its lower end a deeply insertable into the ground Suction mouth for sucking in dredged material and on one between the pump and the lower one The point at the end of the suction pipe has a water inlet opening connected to a water supply line, characterized in that the water supply line (16) is connected to a pressurized water pump (14) and that control members are arranged which control the water pressure of the water inlet opening (26, 126) Adjust pressurized water to maintain the desired concentration of the dredged material. 3. Suction excavator according to claim 2, characterized in that in the water supply line (16) a water jet pump (23, 123) is switched on between the pressurized water pump (14) and the water inlet opening (26, 126).