DE1955944A1 - Method for loading a space of a suction dredger with sand - Google Patents

Description

Il Kon / HH, Pall 63 PatentonwSlfe I £ 0 0 b

Woileeh-Koch-Haibach β, N OV, J969

N.V. Ingenieursbureau voor Systeme en Octrooien "Spanstaal" -Botterdam, the Netherlands.

"Method for loading a space of a suction dredger with sand "-. -

The invention relates to a method for loading a space of a suction dredger, in which a suspension of Sand and water during a performed in at least two steps Load is pumped into the tree.

Such a method is known. In a first loading step, a suspension of water with sand is in pumped the tree. When the tree is completely filled, there is only a relatively small amount of sand in the tree. In a second loading step with overflow of the Tree's additional suspension is pumped into the tree until the amount of sand in the tree does not increase significantly.

The rate of settling of sand is of the same size as the Grains and the flow rate of the suspension dependent.

With a certain tree cross-section, depending on the sand settles, the free flow cross-section is above the. The settled sand becomes smaller, whereby with a constant debit of the pump the current speed increases to a value at which no more sand can settle and at which all the sand in the sucked up suspension flows over the edge again. The sand content that can be achieved with a certain grain size, a certain debit of the pump and a certain tree cross-section divided by the tree content is called the stiffness factor (Bi ¹ ).

Since the specific gravity of nasal sand is about 2,

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The space, also known as the "hopper", is normally about half of the load-bearing capacity in m of sand suction dredgers of the ship.

Because such a bar can not be completely filled with sand by the "BP", it has already been suggested to provide the tree with a standing band, in which edge pleated flaps are arranged, so that by the way In the same circumstances, a little more sand can be introduced into the seam, while even in a third loading step, by letting the sand settle after the pump has been switched off, and then the upper water by means of the overflow valves can drain, sand can be introduced into the room * again. This third loading step can still be repeated. ,

However, this known method is time-consuming and yet does not achieve a satisfactory loading of the room.

The invention aims to shorten the loading time. For this purpose, the method according to the invention is thereby indicates that, in a first step, suspension is pumped into the space until the suction dredger is essentially up to its maximum permissible (load capacity is loaded, and in a subsequent second step additional suspension is pumped into the room, while at the same time, by lowering AbfMessmittel depending on the weight the cargo of the space, water flows off, so that the suction dredger is essentially at its maximum allowable Carrying capacity remains loaded.

Perner the invention provides a suction dredger comprising a room and a pump, by means of which suspension of sand and water '' is pumped into the room, marked by charge measuring devices that regulate the drainage medium.

Perner envisions the invention, the suction dredger 00982T / 1816 '

"to be loaded with sand up to its maximum permissible load-bearing capacity. For this purpose, the volume of the room is preferably so large that the suction dredger is up to its maximum permissible Load bearing capacity is when the space is essentially completely filled with a suspension of sand and water is.

Palis the absorbed suspension has a specific weight of about 1.2, after carrying out the first loading step, only 20 $ of the seam is filled with sand, while no more suspension can be poured into the room without further ado, because otherwise the maximum permissible load-bearing capacity of the suction dredger is exceeded.

Therefore, in the method according to the invention, as soon as the room until "is loaded to its full capacity, a drainage device, the capacity of which, for safety reasons, is considerably greater than that of the pump, while at the same time Pampen of additional suspension, in the room, put into action.

The drainage means preferably comprise. at least one Flow lever with a depth-adjustable inlet.

With regard to safety, the suction dredger according to the invention is preferably characterized by a Load measuring means-controlled safety device that becomes effective when the weight of the load in the room exceeds a predetermined value Value exceeds.

This safety device lowers drainage activates an alarm device, switches off the pump and / or sets unloading means to remove sand from the in an emergency Room in operation.

An additional advantage of the method according to the invention

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is the fact that the pump is immediately deep below the water level, resulting in an increase in pump suction of about 1 m water column.

The mentioned and further features of the invention are explained in more detail below with reference to a drawing.

Pig. 1a and 1b show graphically the known method for Loading a suction dredger;

Pig. 1c shows a cross section of a known suction dredger;

Pig. 2a and 2b graphically show the method according to the invention;

Pig. 3 shows a schematic longitudinal section of a preferred one Execution of a suction dredger according to the invention;

Pig. 4 shows a top view of the suction dredger according to Pigur 3 and 4

Pig. 5 shows a block diagram of the control and safety devices of the suction dredger according to Piguren 3 and 4.

In Pig. 1a and 2a is the total volume by dash-dot line V. of suspension and settled sand and with solid line Vg the volume of the settled sand and in Pig. 1b and 2b is the total weight of suspension and settled sand by dash-dot line W. and by solid line Wg indicates the weight of the settled sand according to the time scale.

When comparing the method according to the invention with the method in Figures 1 and 2, the pump debit is the inflated Suspension and the maximum permissible load capacity of the suction dredger are roughly the same.

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To carry a volume Vqtt m wet sand (Pig. 1a) a suction dredger is used in conventional methods. ship with a maxisial space volume ¥ “applied by means of foldable flow flaps 6 can be reduced to a volume V.

When carrying out a known method is in a room 2 of a suction dredger 1 "de-r Fig. 1c during a first loading step 3, which begins at time 0, and • at time A, in which the tree 2 all the way to the top Volume 5 filled, is.t, ends ,. Pumped suspension. The tree 2 has flow flaps 6, which during the first loading step 3 are closed. In this first loading step 3, the volume Vg and also the weight Gg of the 'settled sand' increases strong too. During the subsequent loading letter 4 in the During the time AD, suspension is continuously being pumped into tree 2, while the same amount of liquid is continuously being pumped into tree 2 increasing content of sand overflows. The increase in itself The deposited sand is so small at time D that continuation of the second loading step 4 is not advisable. Therefore, the pumping in of the suspension is stopped at the point in time D and in a third loading step it is poured into the sand the suspension offered the opportunity to break away.

At time E v / the flow flaps 6 ground brought 6 ', so that then flows off the upper water in the flow position. ¹ The volume of the room is then equal to V. Thereafter, in a fourth loading step 8, the flow flaps 6 are closed again, and the space 2 is again completely pumped full of suspension in the period FG. In the period GH the sand settles in the suspension while no suspension is being pumped in. At the point in time H, the desired volume of sand Vg ^ is reached.

In FIGS. 3 and 4, a suction dredger for carrying out the method according to the invention is shown.

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This suction dredger ship 11 consists of a drag suction dredger, with a tree 12 and a pump 10, on the one hand is connected to a suction pipe 9 and on the other hand to a Schilttrohr 15 and with flow lifters 16 pivotable deep into the tree 12 and forming drainage means. Each flow lifters 16 has a stationary siphon tube 41, which on the one hand to a drill 20 and on the other hand via a flexible line 42 to an adjustable one articulated to the siphon tube 41 Inlet mouth 43 is connected, which is actuated by means of a hydraulic power device 17. At the On the lower side of the tree 12 there are funnel-shaped outlet holes 18 provided with discharge flaps 19. Of the Tree 12 could be divided into two by means of a longitudinal partition be divided equally long parts. The suction dredger could also instead of one, have two cargo holds one behind the other.

The loading of this suction dredger takes place according to the invention as follows: ■,

In the tree 12 is from the suction pipe 9 in a first Loading step 13 via the rubble pipe 15 by means of the pump 10 sucked up suspension is pumped until the suction dredger is loaded to its maximum permissible load capacity.

The tree is now covered with a sand-water mixture. filled, from which a volume of sand V \ _B settles in tree 12 at time B. The flow lifters 16 are now in position 16B. In the second loading step 14 that now follows, additional suspension is pumped into the tree 12 while the flow jacks 16 are introduced into the tree 12 to such a depth that so much liquid flows through the flow jacks 16 and the bores 20 connected to them into the outboard water flows so that the suction dredger remains loaded up to * ». to its maximum permissible load capacity. The flow lifters 16 gradually decrease from position 16B

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off to position 16C.

Pig. 2 clearly shows that the total required charging time OC of charging steps 13 and 14 is considerably less than that in the known Pig method. 1 total required loading time OH, while the sand volume Vg _{C is} equal to the sand volume V «™ ·" of Pig. 1. The short loading time OC is a consequence of the fact that in the method according to the invention the suction dredger is always up to The total weight W. is then always at its maximum (see Pig. 2b), while the total weight ¥ + in Pig. 1b gradually increases in the second loading step 4, but always remains below the maximum value W.

The cargo is measured with pressure sensors 22, which are each arranged at the bottom of the suction dredger 11 and which each comprise a pressure-sensitive membrane 23 which delimits a chamber 24, which chamber is connected to the outboard water 21. Each pressure transducer 22 receives a pressure corresponding to its immersion depth, which is a measure of the draft of the suction dredger and its cargo. There are nine pressure transducers 22, which are arranged on port, starboard, the longitudinal surface of the ship, in front of and behind and in the middle of the suction dredger.

Preferably, during the second loading step 14, the associated one is automatically used for each loading condition Hopper volume adjusted so that the excess volume is minimal.

In Pig. 5 the automatic control device for carrying out the method is shown schematically.

Here are 25 ", 25 _Λ and 25 _a the recipient of the information

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the port side, central resp. on the starboard side independently arranged load pick-up 22 (Pig. 3 and 4). From this information, the respective loading depths are calculated in arithmetic units 26, 26 and 26 _O. The results of this are fed to the draft * and inclination calculation unit 27, which feeds the draft indicator 28, inclination indicator 29 and the safety device 30 with information, while the operating unit 26 provides information about the loading depth on the starboard side to the comparison and calculation device 31 _o forwards the signals to the signal converter 32 _ra for the steamer board flow lifter 16 ^, so that it _{can actuate the control slide 33 S of} the power _{device 17 O} des'Fliessheber 16_.

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unit 31 _c forwards information on the central loading depth to both signal converters 32 and 32,

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unit A in a similar manner signal converter 32 and thus Flow lifter 16 can be operated.

As a result of the fact that the calculation device 31 sends _n data as reference values to both signal converters 32 and 32, a "list" created by uneven loading is corrected.

In the event of overloading or an impermissible list or both, caused by the normal automatic correction are not sufficiently eliminated, the safety device 30 gives signals to an alarm device 34 in FIG In the form of a red lamp, to an acoustic alarm device 35 and to the Sicherheitsautoma.t 36, which the flow lifter 16 " by means of signal converters 32_ and 32_ in the lowest position

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brings the pump 10 by means of signal converter 37 turns off or. by means of signal converter 38 opens the unloading flaps.

However, in the event of a failure of the automatic control device to maintain an operating device, however, are automatic by means of actuators 39 »40_ and 40_

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controlled devices also by hand, e.g. from the BrUclce, to operate.

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ORIGINAL

By using multiple load meters, "the danger is." the warning that the danger limit has been exceeded avoided. When soaking up a suspension with a low concentration of sand, it is conceivable that, though a large space 12 is selected, this tree 12 is already completely filled with suspension while the suction dredger has not yet been loaded to its maximum permissible load capacity.

Then it is carried out until the point in time at which the load has reached the maximum permissible load capacity of the suction dredger has, the tree 12 is still refilled with suspension, while the space 12, which is kept at its maximum volume Overflows.

Only then is additional suspension permitted, with simultaneous drainage of water with the aid of the Pliess lifter 16, which are controlled by means of loading meters 28 and 29 in such a way that the ship continues essentially remains loaded at its maximum permissible load capacity.

The suction dredger 11 preferably comprises a water pump 45 which carries outboard water 21 via an inlet pipe 46 inflates and the over lines 41 to jet mouth. pieces 48 are connected, which are arranged in the siphon tubes 41 and which serve as jet pumps when the siphon effect of the flow siphon 16 is started, if this is the case necessary is.

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It should be noted that after the second loading step 1.4, the pump 10 is switched off and the journey with the loaded Suction dredger can already start. In the following period CD during the journey, the sand settles, which is located in the suspension present in the nock.

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■ ORIGINAL if & P £ C7SD

At the point in time D, all is settled over the Sand stagnant liquid drained, leaving the suction dredger to a certain extent during the laden beise is loaded below its maximum permissible load, which means that the travel speed is greater.

If the level of the settled sand is lower should be than the outboard water level, the liquid can flow through the jet nozzle 48, which works as a jet pump yet be sucked away from this low level. ,

After this liquid has been sucked off, the flow lifters become raised to its upper position.

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Claims (10)

PATE II TAITS.-PHUECH-E AJ Method for loading a tree of a suction dredger, in which a suspension of sand and water is pumped into the tree during a loading carried out in at least two steps, characterized in that in a first step (13) suspension is pumped into the tree (12) is pumped until the suction dredger (11) is loaded essentially up to its maximum permissible load capacity, and in a subsequent second step (14) additional suspension is pumped into the tree (12), at the same time, by lowering drainage means (16) Depending on the weight (W.) of the cargo on the tree (12), water flows off, so that the suction dredger (11) remains loaded essentially at its maximum permissible load capacity. 2. The method according to claim 1, characterized in that the second step (14) is carried out until the suction dredger (11) is loaded with sand substantially up to its maximum permissible load-bearing capacity. 3 · Suction dredger, comprising a tree and a pump by means of which a suspension of sand and water is pumped into the tree, characterized by charge measuring means (22) which control drainage means (16). 4. suction dredger according to claim 3 » characterized in that the volume of the tree (12) is so large that the suction dredger (11) is loaded up to its highest permissible load capacity when the tree (12) is essentially entirely with a suspension of water and Sand is filled. 5. Saugbaggfcrschiff according to claim 3 or 4ι marked thereby . shows that the drainage means (16) comprise at least one plies lifter (16) with a depth-adjustable inlet (43). 0 0 9 8 2 t / 1 5 1 6 6. Suction dredger according to one of claims 3-5 » characterized by a load measuring means (22) -controlled safety device (30) which becomes effective when the weight of the cargo in the Eaumes (12) exceeds a predetermined value. 7. suction dredger .nach one of claims 3-6, characterized by a safety device (30) which is controlled by charge measuring means (22) and lowers the discharge means (16) when the weight of the cargo of the Eaumes (12) is a predetermined value exceeds. 8. Suction dredger according to one of claims 3-7, characterized by a safety device (30) which is controlled by Ladungsmessmi'ttel (22) and which makes an alarm device (34) effective when the weight of the cargo'des Eaumes (12) exceeds a predetermined value. 9. suction dredger according to one of claims 3-8, characterized by a safety device (30) which is controlled by Ladungsme'ssmittel (22) and which turns off the pump (10) when the weight of the cargo of the tree (12) a predetermined Value exceeds'. 10. suction dredger according to one of claims 3-9 »ge characterized by a safety device (30), which is controlled by Laclungsmesssiittel (22) 'and the Entladeinittel (19) is in operation for removing sand from the tree (12) when the weight of the cargo in the space (12) exceeds a predetermined value. 00982t / 1516