NL7906997A - TRANSPORT DEVICE. - Google Patents

Description

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* O&K Orenstein & Koppel Aktiengesellschaftj ^ in Lübeck, Federal Republic

Germany

Transport device.

The invention relates to a transport device for transporting sludge, in particular ore sludge, from great depths with a transport tube terminating in a suction mouth and equipped with a transport pump.

A transport device of the above-described type is known, which consists of a transport tube, the lower end of which is movable and is guided in a cylinder on its circumference. In this case, a drive device engages between the cylinder on the one hand and the lower end of the transport tube on the other, with the aid of which the two parts are moved relative to each other and spring. The cylinder is provided with one or more inwardly opening check valves and the transport tube of eaa upwardly opening check valve.

It is also known to design the hydraulic drive in such a way that it serves not only to obtain the pump movement but also to obtain high-frequency vibrations during shaking. The lower end of the cylinder is conical and tapers to a point. Inwardly opening check valves are provided, which are covered by protective grids. The 20 cylinder is provided with support feet distributed on its circumference. The cylinder resp. the transport tube can be provided with a controllable floating member whose specific weight is adjustable.

The shaking movements must serve to aid penetration into the sludge and prevent the formation of channels which possibly extend through the sludge up to the salt layer.

The object of the invention is to provide a transport device for sludge, with the aid of which also sludge with a high viscosity over relatively large transport paths or. Can be transported under relatively high 7906997 V-transport \ 2 transport pressures · In addition, the transport devices must be suitable for relatively high temperatures of the sludge to be transported. The temperature of the sludge to be transported can be up to about 80 °. The swallow can be specific

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5 have a weight of 1.3 g / cm. However, it must also be possible to transport sludge of greater or less specific weight with the present device. The present device should in particular also serve to transport ore sludge from great depths, wherein above the ore sludge layer there is a salt solution zone with a relatively large specific weight of, for example, 1.2 g / cm. The transport device must be designed in such a way that saline solution from this zone does not enter into the ore sludge to be transported. enters the transport device. The ore sludge to be transported can be deposited on the sea bed at a depth of about 2500 meters and have a thickness of about 20 to 100 meters. The viscosity of the ore sludge can be about 120 c poise ... u

The ore sludge occurs in a relatively solid deposit, possibly with thixotropic properties. The material to be transported can be mixed with larger chunks, such as, for example, basalt blocks. The deposition site may be covered with an approximately 200 meter thick layer of concentrated saline. The invention must overcome these transport difficulties.

The invention consists in that the suction nozzle is designed as a vibrating screen. The sieve can herein have a conical shape and have points directed downwards, the vibrating device being perpendicular.

The device according to the invention has the advantage that the bottom material is loosened by the vibrations and the suction work is thereby considerably facilitated or reduced. the energy to be used is reduced. The screen prevents all obstacles that endanger a transport device, for example with a impeller pump. In addition, the saline above the deposit is not drawn in.

According to another embodiment of the present device, the lower end of the conveying device can carry pressurized water outflow nozzles 35. For instance, a number of such outflow nozzles can be arranged on the conveyor 7906997

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4 * - * 3. The water jet is preferably directed in the direction of the area of the sieve, respectively. toward its outer surface.

Furthermore, in the region of the tips of the conical sieve, flow nozzles for water can be provided, which are provided by a retaining member extending longitudinally over the sieve by means of a holder arranged on the conveyor.

The additional supply of pressurized water contributes to loosening the soil material. The supply of pressurized water allows for adjustable thinning and mixing of the loosened material.

The device according to the invention can be designed in different ways. A simple embodiment of the construction consists in that the conical sieve is attached at its base to a support device, which is slack on the bar. is guided in the lower end of the transport tube and is pivoted in a perpendicular direction. The lower end of the transport tube (suction head) can support the drive of the vibrating screen. For this purpose the sieve resp. its supporting ring are provided with a number of connecting bolts guided in the vibration direction, which are provided at their other end with rollers, which are supported on a rotating ring disc surrounding the transport tube, the surface of which in the vertical direction of wave-shaped elevations and resp. floors is provided.

The connecting bolts can thereby bear tension springs, which are supported on the one hand against the base of the vibrating screen and on the other hand against a supporting bearing arranged on the transport tube. Thereby a bias is obtained which continuously presses the rollers against the ring disk.

When the cam disc is rotated, the vibrating screen is moved up and down in accordance with the rotational speed with an adjustable vibration number. When the sieve bumps with its lower end, it is automatically lifted away from the shaker so that the drive disc is free.

For further protection of the drive, a centrifugal clutch can be fitted between the drive and the ring disc.

A simple embodiment consists in that the ring-35 discs are alloyed in pendulum bearings.

7906997 \ P> *

It is expedient for the electric drive to be housed in a separate housing (drive carrier) surrounding the lower end of the transport tube, the connecting bolts of which are opened watertight to the outside. The watertight seal may consist of membrane discs attached to the connecting bolts and circumferentially clamped in the housing. The housing can be provided with an oil filling and via a buffer tank pipe.

The sieve may be formed from trapezoidal wires.

For guiding the vibrating screen, the latter can bear guide plates running perpendicular to its outer surface.

The suction head can be attached to a suction head shaft, which consists of two concentric tubes, the inner tube of which is the suction tube and where the interspace serves for the transport of water under pressure. The suction head shaft can consist of a number of tube baffles 15, the inner tube of which are connected to each other via plug connections with O-ring seals. On the other hand, the outer tubes of the bulkheads of other flanges and. seals for connection to each other are provided.

The. suction head resp. the suction head shaft can travel via a construction-20 part with spring damping. surface running pipe string are connected. This keeps vibrations away from the transport pipe. Furthermore, the spring damping construction part can be provided with a track sensor, by means of which the excessive movements of the suction head relative to the connecting transport tube are indicated. In this way it is possible, for example, to check in a simple manner whether the vibrating screen is on the bottom.

The compressed water line may be provided with a riser for supplying water cooling to the drive motor.

The invention will now be further elucidated with reference to the drawing.

Fig. 1 schematically shows the construction according to the invention.

Fig. 2 shows a large-scale section of the vibrating screen and its drive.

Fig. 3 shows the top construction part connecting to FIG. 2.

Fig. h shows a cross section of two tube baffles containing the suction 7906997 P <# 5 head.

Fig. 5 shows a side view of the construction part with spring damping.

Fig. 6 schematically shows a compressed water installation.

5 A transport pipe B runs from the ship A to the seabed.

The mounting of the transport tube in detail to the ship is not shown.

A pump set C is included in the transport tube B, which on the one hand contains the suction pump D and on the other hand a pressure pump E fed by the surrounding sea water.

The suction head shaft G is attached to the lower part of the transport tube B via a construction part F with spring damping. This consists of a number of tube partitions, each consisting of an inner tube H and an outer tube I. The inner tube H serves as a suction tube. The space between the pipes H and I serves for the transport of compressed water and is connected to the compressed water pump E via a flexible pipe K.

The suction head L is attached to the lower suction head shaft G.

At the lower end of the suction head, the vibrating screen 1 is attached, which is conical and is connected at its base with a support ring 2. The sieve may be mounted in a frame for strength. Between the solid point: 1a and the openings for the compressed water supply and the supporting ring are three ribs 3 on the circumference, between which the individual sieve segments are welded. The screens can have a mesh size of 10 mm; in order to prevent clogging they are formed from trapezoidal separate wires.

Guide plates k are fixed over the three screen segments, which are efficiently connected to the tip on the one hand and to the supporting ring 2 on the other.

The carrier ring 2 carries perpendicularly guided connecting bolts 59 on its circumference which are guided within the drive carrier 6.

The drive elements. are located in the space between the suction tube H and the protective jacket M. An underwater motor 7 is mounted there, the shaft of which is parallel to the suction tube H and which shaft 35 drives the ring disc 9 with pendulum roller bearings, which is mounted on a toothed ring 9a, connected via a round set 8 to this. It is provided on its top side with three corrugated elevations, in a sinusoidal axis of the same shape, on which run rollers 10a run, which are attached to a drive ring 10, which connects the upper ends of the connecting bolts 5. Springs 11 provide continuous contact of the rollers on the ring disc, which tension the connecting bolts 5 continuously and prevent the rollers from lifting during normal operation. As a result of the rotation of the ring disc, a vibrating movement of the sieve is obtained.

When the springs are loaded, for example due to a hard setting of the sieve on the seabed, which is not controlled, the track rollers are lifted, the ring disc runs free. The connecting bolts 5 are guided in sleeve bearing bushes 12. The annular space of the drive carrier, which is continuously filled with oil, is connected to a buffer vessel 13 for pressure sensing.

For a further protection of the drive of the ring disc, a centrifugal coupling 1 ^ is arranged between the drive inotor and the drive element.

For sealing the connecting bolts, these are provided with rubber membranes 18, which are clamped in the housing 20 on their outside.

The oil serves both for lubricating the movable parts and for the heat exchange between the Er motor and the environment.

In the vicinity of the suction mouth opening, outflow nozzles 15 are attached to the suction head and are connected to each other via a ring tube 15a and to the pressurized water space. In addition, within the sieve 1 there is provided a stationary fixed retaining member 16 for the outflow nozzles, at the ends of which are attached steam nozzles 16a, which are also fed through the pressurized water space and which pass through the point 1a of the vibrating sieve. The outflow nozzles of the outer ring are arranged in groups with different jet directions. The compressed water is used to remove obstacles and to loosen the soil. With a change of the total free exhaust cross section through the. exchanging inserts for the uterine nozzles or by closing separate outflow nozzles, a number of possible operating states can be achieved.

The suction head carries a support body 2i surrounding the screen, with 7906997 4 * ψ 7 by means of which the device is held during mounting and which also serves to protect the tool during lowering against larger rock chunks or the like.

The spring damping construction member F compensates for the vibrations 5 and which may be transferred from the vibrating screen to the drive carrier and to the shaft. At this location it is possible to measure the pressing of the device on the bottom or the force required for pulling the device out of the sludge with an inductive track sensor 12. Length changes of the transport tube can be absorbed by a steel compensator within the construction part with spring compression.

The compressed water required for the suction screen is obtained by a compressed water pump 31 running on the same axis with the frequency-controlled main pump. Since a coupling of this type is unfavorable for the extraction, a control of the flow through a mixture controller 32 is carried out. This construction of the compressed water pump ensures that the nominally required transport performance is achieved even at the lowest speed of the main pump.

The electrically operated k / 3-way valve 33 moves the control piston of the mixture controller, using the compressed water as the working medium for the mixture controller and the hf3-way valve. The amount of pressurized water is measured with a standard venturi outflow nozzle 3¼ and a capacitive differential pressure sensor 35 · Two check valves 36 and 37 with pre-positioned filters are built in to bleed the control lines during lowering.

Due to the submersible pump unit located at a depth of approximately 2000 meters, the supply of compressed water to the suction screen placed at a depth of approximately 200 meters is effected by means of a hose 38, which is made of a rubber fabric.

Within the suction head, a partial flow of the compressed water is used for cooling the motor 7. A parallel-mounted, fixed differential pressure valve 39 opens at a flow rate of a quantity greater than that required for cooling, thereby limiting the pressure drop in the cooler. Behind the valve there is a branch 35 of the compressed water to the two outflow nozzle structures, namely via the sieve 1 and in the sieve tip 1a.

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The vibration of the sieve in connection with its conical design means that obstacles, which come to the sieve jacket through the suction flow, are moved in the direction of the sieve tip in the manner of the operation of a vibrating sieve. In this way, a blockage of the suction area is prevented.

A purpose of the vibration is to mix compressed water and sludge. The applied vertical plates also serve for an effective transfer of vibrations into the soil.

7906997

Claims (20)

Transport device for transporting sludge, in particular ore sludge, from great depths with a transport tube terminating in a suction nozzle and equipped with a transport pump, characterized in that the suction nozzle is designed as a vibrating sieve (1). Transporting device according to claim 1, characterized in that the vibrating screen (1) is conical and has a downwardly directed point, the vibrating device being vertical. Conveyor according to claims 1 and 2, characterized in that the lower end of the conveyor carries compressed water steam nozzles (16a, 15). k. Transport device according to claims 1 to 3, characterized in that a number of compressed water outflow nozzles (15) are arranged on the transport tube above the sieve (1). Transport device according to claim 4, characterized in that the water jet in the direction of the region of the sieve (1) or. facing its outer surface. Conveyor according to claims 1 to 5, characterized in that in the region of the tip of the conical sieve (1) 20 compressed water outflow nozzles (16a) are provided, which are passed through a sieve through a conveyor ( 1) longitudinally retaining retainer (16) are attached. Transporting device according to claims 1 to 6, characterized in that the conical sieve (1) is mounted on its base in a supporting ring 25 (2), which with clearance at resp. the lower end of the transport tube is mounted perpendicularly and can be vibrated. Transport device according to claims 1 to 7, characterized in that the lower end of the transport tube (suction head L) carries the drive (7) of the vibrating screen (1). Transport device according to claims 1 to 8, characterized in that the screen (1) or its supporting ring (2) carries a number of connecting bolts (5) guided in the vibration direction, which are provided on their other end with rollers (10a), which bear on a rotating ring disc (9) surrounding the conveying tube, of which the surface in vertical direction of wave-shaped elevations resp. deepening is seen before 7906997 »Τ„ .S. Transport device according to claim 9, characterized in that the connecting bolts (5) bear tension springs (.11), which are on the one hand on the base of the vibrating screen (1) and on the other hand on a counter mounted on the transport tube 5. are supported. Transporting device according to claim 9, characterized in that the ring disc (9) is mounted in pendulum bearings. Conveyor device according to claims 9 to 11, characterized in that a single-centrifugal clutch (1U) is arranged between the electric drive (7) and the ring disc 10 (9). Transport device according to claims 1 to 11, characterized in that the electric drive (7) of the ring disc (9) is in a separate housing (drive-carrier M) surrounding the lower end of the transport tube (H). housed, the 15 connecting bolts (5) being led out watertight. Transporting device according to claim 13., characterized in that the watertight closure of the connecting bolts (5) consists of. Membrane discs (18) attached to the housing and circumferentially attached thereto. Transport device according to claims 13 and ih, characterized in that the housing is provided with an oil filling and is connected via a pipe to a buffer vessel (13). Transporting device according to any one of claims 1 to 15, characterized in that the screen (1) is formed from trapezoidal wires. Transporting device according to claims 1 to 16, characterized in that the screen (1) carries laterally running guide plates (U) on its outer side. Transport device according to claims 1 to 17, characterized in that the zuxg head is on. a suction head shaft (G) is attached, which consists of two concentric tubes (H, ij), the inner tube (Ξ) of which is the suction tube and the intermediate space for the transport of compressed water. Transport device according to claim 18, characterized in that the suction head shaft (G) consists of a number of tube baffles, the inner tube (H) being connected to each other via plug connections with O-ring seals. 7906997 Transport device according to claims 1 to 19, characterized in that the suction head or the suction head shaft (G) via a construction part (F) with spring damping with the transport housing (which runs to the surface). B) is connected. Transporting device according to claim 20, characterized in that the construction part (F) is provided with a rooster sensor (22) with spring suspension. Transport device according to claims 1 to 21, characterized in that the compressed water line is provided with a branch line 10 for supplying a water cooling of the drive motor (7). 23. Transport device substantially as indicated in the description and / or assembled in the drawing. 7906997