SE511784C2 - Flushing device for internal flushing of tanks esp. tanks in ships - Google Patents

Abstract

The flushing device is for internal flushing of tanks, preferably tanks in vessels or ships. A turbine wheel (13) in a turbine device (8) is mounted in a supply conduit (10) so that the wheel (13) is driven by the flow of flush liquid in the supply conduit (10). The turbine wheel (13) is provided to operate a driving assembly located outside the supply conduit (10) and provided to bring a flush-liquid pipe to rotate and at the same time revolve or turn flush nozzles (7). A magnetic coupling (50) is provided to transfer by means of magnetic power, the rotary motions of the turbine wheel (13) from the interior of the supply conduit (10) to the driving assembly (9) located outside the supply conduit (10). Furthermore, the turbine wheel (13) is displaceably mounted for increasing or decreasing the speed of rotation.

Description

511 784 the inner magnetic body that magnetic forces arising between the magnetic bodies allow the rotational movement of the inner magnetic body to be transmitted to the outer magnetic body, and the magnetic coupling being arranged at the supply line outside the tank.

The document SE-B-445 823 describes a flushing device with a turbine wheel which is driven by flushing fluid. This turbine wheel has a shaft which passes out of the supply line through a hole in it and the movement of the shaft is transmitted to the flushing fluid pipe and flushing nozzles to rotate them. A disadvantage of the shaft passing through a hole in the supply line is that it is black to prevent leakage between the shaft and the supply line.

The document US-A-4 913 346 describes a flushing device with a magnetic coupling located at a supply line outside the tank and with a turbine wheel driven by the flushing liquid. This known rinsing device has an outer drive device which is intended to rotate an inner shaft for rotating the rinsing nozzles of the rinsing device. The rotational movements of the drive device are transmitted to the inner shaft via said magnetic coupling which has an outer part which cooperates with an inner part which in turn cooperates with the inner shaft. Since said magnetic coupling transmits magnetic forces from the supply line into it, it is not useful for flushing devices where a turbine wheel driven by the flushing liquid in the supply line drives a flushing liquid pipe and flushing nozzles outside the supply line to rotate.

U.S. Pat. No. 5,092,523 discloses a flushing device for flushing the inner walls of tanks and the same has a flushing nozzle housing with two nozzles, a turbine device with a turbine wheel driven by flushing liquid and a magnetic coupling for transmitting the movements of the turbine wheel 511 784 to a rotatable flushing nozzle holder so that it is turned.

The magnetic coupling has a closed wall portion between two cooperating magnetic coupling parts. Said flushing nozzle housing is arranged inside the tank, which means that the magnetic coupling and the turbine device are extremely difficult to place.

The object of the present invention is to further develop known devices so that internal parts of the magnetic coupling and other internal parts become easily accessible for service, disassembly or other operations. According to the invention, this has been achieved in that the flushing device exhibits the features which essentially appear from the following claim 1.

Because the coil device has the said characteristics, the inner part of the magnetic coupling and other parts of the supply line become extremely easily accessible for various operations.

The invention will be explained in more detail below with reference to the accompanying drawings, in which Figure 1 with a side view and partly in section illustrates a coil device with a device according to the invention; Figure 2 illustrates a section of a supply line included in the coil device according to Figure 1 and a turbine device arranged therein; figure 3 illustrates parts of the supply line according to figure 2 with the turbine device in a different position; Figure 4 illustrates a section IV-IV of the turbine device according to Figure 3; Fig. 5 schematically illustrates a drive unit included in the coil device according to Fig. 1 and parts connected thereto; figure 6 schematically and partly in section illustrates parts of the drive unit according to figure 5; Figure 7 illustrates a section VII-VII of a part included in the drive unit according to Figure 6; and Figure 8 finally illustrates the parts of the drive assembly illustrated in Figure 6 in a different position.

The figures illustrate a flushing device 1 for internal flushing of tanks, preferably ship tanks 2, the upper side 3 of which is indicated by dotted lines in figure 1.

The flushing device 1 has a fastening plate 4 via which it is mounted on said upper side 3 of the ship tank 2.

The flushing device 1 has an inlet housing 5, a flushing liquid pipe 6 with flushing nozzles 7, a turbine device 8 and a drive unit 9. The inlet housing 5 is placed on top and attached to the mounting plate 4. The flushing liquid pipe 6 is rotatably mounted on the inlet housing 5 and it slides downwards. the vessel tank 2 to be flushed.

The flushing nozzles 7 are rotatably mounted on the flushing liquid pipe 6 and they are intended to rotate relative thereto at the same time as the flushing liquid pipe 6 is rotated.

The turbine device 8 is arranged in a supply line 10 which is intended to lead flushing liquid 11 to the flushing liquid pipe 6 and via this to the flushing nozzles 7 which are intended to direct flushing liquid jets 12 towards the insides of the ship tank 2.

The flushing fluid flow in the supply line 10 is under pressure and the type of flushing fluid 11 may vary depending on the substance present in the vessel tank 2 to be cleaned. Thus, the rinsing liquid can be, for example, cold or heated water with or without additives. If the vessel tank has contained oil, the flushing fluid may be heated oil which is used to remove contaminants on said insides.

The turbine device 8 has a turbine wheel 13 which is driven by the flushing fluid 11 to rotate as it flows through the supply line 10 to the flushing liquid pipe 6. The turbine wheel 13 is intended to drive the drive unit 9 arranged outside the supply line 10. This is arranged to cause the flushing liquid pipe 6 to rotate and cause the flushing nozzles 7 to rotate simultaneously.

The turbine wheel 13 of the turbine device 8 preferably drives a gear 14, preferably of the planetary gear type, which is intended to substantially shift down the rotational speed of an incoming shaft 15 driven by the turbine wheel 13, for example in the ratio 1:30 from the same to the output of the drive unit 9. shaft 16. Thus, for example, the rotational speed of the incoming shaft 15 of approx. 1500 rpm. in gear 14 is shifted down to approx. 50 rpm. on the output shaft 16.

The shaft 16 cooperates with a motion transmission device 17 included in the drive unit 9 which transmits its rotational movement (arrow A, figure 5) to a rotary gear 18 for rotating parts included therein, whose rotational movement (arrow B, figure 5) via a downward movement transfer means 19 are transferred to the flushing liquid tube 6 to rotate it. The motion transmission device 17 and the rotary gear 18 are shown only schematically because they can be designed in accordance with previously known devices in coil devices or in another suitable manner.

The motion transmitting device 17 is also intended to transmit its rotational motion, for example via an output shaft 20, to another motion transmitting device 21, the rotational motion of which (arrow C, Figure 5) is transmitted to a lifting gear 22 in which the rotational motion of a member included therein organs are transferred to another organ contained therein so that the latter obtains a linear reciprocating movement (arrow D, figure 5). The reciprocating member 22 of the lifting gear 22 drives an elongate drive member 23 to perform reciprocating movements in its longitudinal direction. This elongate drive member 23 is directed downwards into the flushing liquid tube 6 and it has drive portions 24, preferably teeth, which cooperate with drive wheels 7a, preferably gears, on each flushing nozzle 7 so that the flushing nozzle 7 is rotated about a horizontal axis of rotation of the flushing shaft 6. as the elongate drive member 23 performs reciprocating movements.

The turbine wheel 13 is so movably arranged in relation to at least one adjacent, tubular part 25 that the speed of the flushing liquid flow E at the turbine wheel 13 and thus the rotation speed and / or kinetic energy of the turbine wheel 13 can be changed in relation to the speed of the flushing fluid not shown), to which the supply line 10 is connected, allows.

In order to be able to quickly carry out this individual change of the rotational speed and / or kinetic energy of the turbine wheel 13, the movement of the turbine wheel 13 relative to said tubular part 25 can take place by means of an adjusting device 26 which is operable from the outside of the supply line 10, i.e. one does not need to open the supply line 10 to perform said setting.

In the illustrated embodiment, the turbine wheel 13 may be movable within such a setting sector S to allow the velocity of the flushing fluid flow to increase locally sufficiently to drive the turbine wheel 13 at the desired rotational speed and / or provide this desired kinetic energy with the pump system such flow rate of the flushing fluid ll.

In the illustrated embodiment, the turbine wheel 13 is arranged on a vertically directed shaft 27 and the same is located in a vertically directed part of the supply line 10. A lower part of the shaft 27 is rotatably mounted at the adjusting device 26 and an upper part thereof cooperates so with a means 28 for transmitting the rotational movement from the turbine wheel 13 to the drive assembly 9, that the shaft 27 is displaceable in relation to said means 28 but is in driving engagement therewith for said transmission of the rotational movements.

To enable this, the shaft 27 can slidably engage in a sleeve-shaped part 29 of said member 28 and the same can have a pin 30 which slidably engages in a groove 31 arranged in the sleeve-shaped part 29.

The turbine wheel 13 preferably consists of a hub 32 conically tapered in the flow direction F of the flushing liquid II with a plurality of outwardly directed turbine blades 33 which are inclined with respect to the longitudinal axis of the turbine wheel 13 and with respect to the flow direction F of each flushing liquid II. flat or arcuate and the same or parts thereof may extend at an angle of 40-50 ° relative to said longitudinal axis. On the shaft 27, in the flow direction F of the flushing liquid 11, a streamlined nose part 34 can be arranged in front of the hub 32 and the hub 32 can be mounted rotatably on the shaft 27 by means of pins 35 or corresponding fastening elements.

The tubular part 25 may be a separate part which is inserted into a dedicated recess 36 in the supply line 10 and which is held in this position by means of at least one fastening means, e.g. a fastening screw 37, which may be screwed from the outside through the wall of the supply line 10 and into the tubular part 25.

The tubular part 25 has seen conically tapered insides 38 in the flow direction F1 of the flushing liquid 11 and these preferably have the same or substantially the same conicity as outer surfaces 39 of the hub 32, i.e. the insides 38 of the tubular member 25 and the outsides 39 of the hub 32 run parallel or substantially parallel in relation to each other, whereby an evenly wide or substantially evenly flow-through space 40 is formed between the outsides 39 of the hub 32 and the insides 38 of the tubular member 25. the outer edges 41 of the turbine blades 33 may, seen from the side, run parallel or substantially parallel to the insides 38 of the tubular part 25 so that the turbine wheel 13 can be adjusted either with the outer edges 41 of the turbine blades 33 extending closely along said insides 38, the turbine the wheel 13 occupies an end position in said setting sector S (see figure 3), in which end position the size of the flow space 40 (flow area) is the smallest, or in another end position substantially further from said insides 38, the flow space 40 being the largest .

The turbine wheel 13 is preferably also arranged and adjustable in different positions within such a setting sector S that the hub 32 in all setting positions is located inside or substantially inside the tubular part 25.

In the illustrated embodiment, the adjusting device 26 has a displacing member which is adjustable from the outside of the supply line 10. This displacing member is, for example, an adjusting sleeve 42 which is provided with 511 784 outer threads 43 and which is closed at its outer end but has an open inner end. The adjusting sleeve 42 is screwed into a threaded heel 44 in the wall of the supply line 10 and a counter nut 45 is screwed onto its outer threads 43 which ensures that it remains in the set position. Arranged in the adjusting sleeve 42 is preferably a spherical bearing element 46, against which the shaft 27 abuts via a carbide body 4 mounted on its end surface. In the adjusting sleeve 42 there may be a lock 48 for holding the spherical bearing element 46 in place and a radial bearing 49 for the shaft 27.

By screwing the adjusting sleeve 42 further into the supply line 10 from the position shown in Figure 2, the shaft 27 and thus the turbine wheel 13 is displaced relative to the tubular part 25, whereby the size (flow area) of the flow space 40 increases.

This reduces the speed of the flushing fluid flow E at the turbine wheel 13 and thus its rotational speed and / or kinetic energy.

The tubular part 25 can be a turbine wheel 13 adjacent part of another design and with a different location and it can also consist of more than one piece.

Furthermore, said adjacent part 25 can be movable relative to the turbine wheel 13 instead of the other way around and in addition it is possible to arrange both the turbine wheel 13 and the adjacent part 25 movable relative to each other in order to achieve the above-mentioned purpose.

The turbine wheel 13 may be of a different type than the one shown and it may be arranged elsewhere in the supply line 10 than in the illustrated location.

Furthermore, the adjusting device 26 can be designed in a different way than the one illustrated and it can be arranged in a different place than the one illustrated. 511 784 10.

In order to be able to avoid holding in the supply line 10 for rotary motion transmitting means, a magnetic coupling 50 is arranged to transmit by means of magnetic force the rotational movements of the turbine wheel 13 from the interior of the supply line 10 to the drive unit 9 arranged outside it.

The magnetic coupling 50 preferably has an inner magnetic body 51, which is arranged inside the supply line 10 and an outer magnetic body 52, which is arranged outside the supply line 10.

The magnetic bodies 51, 52 are arranged in relation to each other in such a way that between these emerging magnetic forces allows the rotational movement of the inner magnetic body 51 to be transmitted to the outer magnetic body 52.

The inner and outer magnetic bodies 51, 52 are preferably permanent magnets and these are preferably annular. Furthermore, they may have the same or substantially the same outer and inner diameters and be centered with a common center line extending in the axial direction of the magnetic coupling 50.

Arranged between a holding means 53 for holding the inner magnetic body 51 and a closed wall portion 54 of the supply line 10 is at least one support bearing 55, which is intended to transfer to the closed wall portion 54 the load to which the inner magnetic body 51 is subjected. direction towards said closed wall portion 54 of magnetic forces arising in the magnetic coupling 50.

In the illustrated embodiment, the support bearing 55 is arranged on the holding member 53 radially inside the annular inner magnetic body 51. 511 784 11.

The inner magnetic body 51 is preferably arranged in a recess 56 in the retaining member 53 and the inner magnetic body 51 is held in place in this recess 56 by means of a cover 57 arranged on the retaining member 53. This cover 57 preferably has an opening for the support bearing 55 which is arranged in a groove 58 in the holding means 53.

The closed wall portion 54 is removably provided on the supply line 10 to release an opening therein, through which opening the turbine device 8 and the parts of the magnetic coupling 50 which are intended to be arranged inside the supply line 10 can be inserted into and taken out of the supply line 10.

The holding means 53 is preferably mounted via an axial and radial bearing part 59 in a bearing sleeve 60, which is arranged in the supply line 10 between the inner magnetic body 51 and the turbine device 8.

The bearing sleeve 60 is removably arranged in the supply line 10 and is removable from it via the opening through which also the inner magnetic body 51 and the turbine device 8 are removable. The bearing sleeve 60 may be arranged in such a space of the supply line 10 which is at least substantially located next to a substantially flow path, through which flushing fluid 11 flows.

In addition, the bearing sleeve 60 may preferably have a drainage hole 61 between said flow path and a space 62 for the inner magnetic body 51 so that the liquid pressure in the supply line 10 does not subject the bearing sleeve 60 to forces in the direction of the inner magnetic body 51.

The outer magnetic body 52 is mounted on an outer retaining member 63 which is attached to the previously mentioned shaft 15. The outer retaining member 63 is arranged in a fastening member 64, which is mountably arranged on the supply line 10 by means of screws 65. to be able to be removed when disassembling the turbine device 8.

The inner and outer magnetic bodies 51, 52 of the magnetic coupling 50 may be of a different type than the one described, they may have a different shape than the one described and they may be arranged in a different way. For example, the magnetic bodies may be annular and one magnetic body may be located inside the other instead of next to each other.

The lifting gear 22 has a threaded part 66 which is slidably mounted in its longitudinal direction and which is connected via a rod 67 to the elongate drive member 23. An annular element 68 is rotatably mounted around the threaded part 66, which is rotated in the direction of rotation H (see Figure 7) of the motion transmission device 21 via a motion transmission means 69.

Arranged on the annular element 68 is a carrier 70 which engages in the threads of the threaded part 66. These have two threads 71, 72 with different thread directions, namely a thread 71 which runs helically in the upward direction and another thread 72 which runs helically in the downward direction. These threads merge at the bottom via the transition portion 73 and at the top via the transition portion 74 into each other so that the two threads 71, 72 together form an endless thread.

When the driver 70 rotates around the threaded part 66, it will, by its engagement with the endless thread 71, 72, displace the threaded part 66 and thus the elongate drive member 23 in the upward direction, whereby the coil nozzles 7 are rotated in one direction. When the threaded part 511 784 13. 66 has been displaced upwards by a predetermined distance, the carrier 70 will intervene from the descending thread 72 to proceed via the transition portion 73 (see Figure 7) to engage the ascending thread 71, whereby the carrier thread the cleaner 70 will drive the threaded part 66 in the downward direction instead and thus the flushing nozzles 7 will be rotated in the opposite direction. When the threaded part 66 is displaced down a predetermined piece, the carrier 70 from engaging the ascending thread 71 will transition via the transition portion 74 to engaging in the descending thread 72, the carrier 70 again driving the threaded part 66 in the upward direction.

By means of this endless thread 71, 72 it is thus permitted that the rotational movement H of the carrier 70 in one and the same direction around the threaded part 66 can cause it to be displaced alternately upwards and downwards without interruption, i.e. the threaded part 66 receives a continuous reciprocating movement D.

To prevent the threaded part 66 from being rotated by the action of the carrier 70, the threaded part 66 has a longitudinal wedge groove 75 in which a wedge 77 arranged on the frame 76 of the lifting gear 22 engages.

The lifting gear 22 may have a different design, provided that the carrier 70, in continuous rotation in one direction, drives the threaded part 66 to continuously perform reciprocating movements. Thus, the threaded part 66, the carrier 70 or means 75, 77 which prevent rotation of the threaded part 66 may be designed in a manner other than that shown and described.

Claims (11)

511 784 14. Patent claim: IIIIIIIIIIIIIIIIIIII Flushing device for internal flushing of tanks, preferably ship tanks, wherein at least one flushing liquid pipe (6) is rotatably arranged in the tank (2), the flushing liquid pipe (6) having at least one flushing nozzle (7) which is rotatably arranged in relation to the rinsing liquid pipe (6), a supply line (10) being arranged to lead rinsing liquid (11) to the rinsing liquid pipe (6) and via this to the rinsing nozzle (7) which is intended to direct rinsing liquid jets (12) towards the tank (2) ) insides, wherein a turbine wheel (13) in a turbine device (8) is arranged in the supply line (10) so that it is driven by the flushing liquid flow in the supply line (10), the turbine wheel (13) being arranged to drive an outside supply line (10) drive assembly (9) arranged to cause the flushing liquid tube (6) to rotate and at the same time to turn the flushing nozzle (7), a magnetic coupling (50) being arranged to transmit the rotational movements of the turbine wheel (13) by means of magnetic force. from the interior of the supply line (10) to the drive unit (9) located outside the supply line (10), the magnetic coupling (50) having an inner magnetic body (51) arranged inside the supply line (10) and an outer magnetic body (52), arranged outside the supply line (10) in such a relation to the inner magnetic body (51) that magnetic forces arising between the magnetic bodies (51, 52) allow the rotational movement of the inner magnetic body (51) to be transmitted to the outer the magnetic body (52), and wherein the magnetic coupling (50) is arranged at the supply line (10) outside the tank (2). characterized in that the supply line (10) outside the tank (2) has a closed wall portion (54) which is removably arranged to release an opening in the supply line (10) outside the tank (2), via which opening the inner parts (51) of the magnetic coupling (50) can be inserted into and taken out of the supply line (10). A coil device according to claim 1, characterized in that the inner magnetic body (51) is arranged in a groove (56) closed in relation to the supply line (10). Coil device according to claim 1 or 2, characterized in that the inner and outer magnetic bodies (51, 52) are permanent magnets, which are preferably annular and have the same or substantially the same outer and inner diameter, which annular permanent magnets are preferably are centered with a common center line extending in the axial direction of the magnetic coupling (50). A coil device according to any one of the preceding claims, characterized in that between at least one holding means (53) for holding the inner magnetic body (51) and a closed wall portion (54) of the supply line (10) is arranged support bearing (55), which is intended to transmit to the closed wall portion (54) the load to which the inner magnetic body 511 784 16. (51) is subjected in the direction of said closed wall portion (54) by magnetic forces arising in the magnetic coupling (50). Coil device according to any one of the preceding claims, characterized in that the inner magnetic body (51) is arranged in a groove (56) in a holding means (53) intended for holding it and that the inner magnetic body (51) is held in place therein. groove (56) by means of a lid (57) mounted on the retaining member (53). Ä Rinsing device according to claim 5, characterized in that the lid (57) has an opening for a support bearing (55) which is arranged in a groove (58) in the holding means (53) and which is intended to be directly or indirectly abut against the closed wall portion (54). Coil device according to any one of the preceding claims, characterized in that in addition to the inner parts (51) of the magnetic coupling (50), the turbine device (8) is also insertable into and removable from the supply line (10) via said opening therein. Coil device according to one of the preceding claims, characterized in that a holding means (53) included in the magnetic coupling (50), for holding the inner magnetic body (51), is mounted in a bearing sleeve (60), which is arranged in the supply line (10) between the inner magnetic body (51) and the turbine device (8), that the bearing sleeve (60) forms both radial and axial bearings for the holding means (53) either directly or preferably via an axial and radial bearing part ( 59), that the bearing sleeve (60) is preferably removably arranged in the supply line (10) and removable therefrom via an opening through which also the inner magnetic body (51) and the turbine device (8) are removable from the supply line (10), that the bearing sleeve (60) is preferably arranged in such a space of the supply line (10) which is at least substantially located next to a main flow path in which flushing liquid flows through the supply line (1). 0) and that the bearing sleeve (60) preferably has a drainage hole (61) between said flow path and a space (62) for the inner magnetic body (51). Flushing device according to one of the preceding claims, characterized in that the turbine wheel (13) has a hub (32) which tapers conically in the direction of flow of the flushing fluid (II) through the supply line (10), that the turbine wheel (13) cooperates with an adjacent part. (25) of the supply line (10), which adjacent part (25), seen in the flow direction (F) of the flushing liquid through the supply line (10), has conically tapered insides (38) and that the turbine wheel (13) is in or against said flow direction (F) displaceable (G) relative to said adjacent part (25) so that the size of a flow space (40) existing between the hub (32) and said insides (38) of the adjacent part (25) increases or decreases , whereby the speed of the flushing fluid flow (E) at the turbine wheel (13) and thus the rotational speed and / or kinetic energy of the turbine wheel (13) can be changed. Coil device according to claim 9, characterized in that the hub (32) of the turbine wheel (13) has outer sides (39) which are parallel or substantially parallel to the inner sides (38) of the adjacent part (25), whereby an even width or in substantially uniform flow space (40) is formed between the outer surfaces (39) of the hub (32) and the inner surfaces (38) of the adjacent part (25), that the turbine wheel (13) is so designed and arranged in relation to said adjacent part (25) ) insides (38) that the outer edges (41) of the turbine blade (33) included in the turbine wheel (13) run parallel or substantially parallel to said insides (38), that the turbine wheel (13) is displaceable in relative to the insides (38) of the adjacent part (25) within such a setting sector (S) that the outer edges (41) of the turbine blades (33) are either close to said insides (38) or substantially further from said insides (38). 11. ll. Spooling device according to any one of the preceding claims, wherein the drive assembly (9) is arranged to drive an elongate drive member (23) with reciprocating movements (D) in its longitudinal direction in order to turn the spool nozzle (7), k) via said elongate drive means (23). characterized in that the drive assembly (9) for driving the elongate drive means (23) has a driver (70) driven by the turbine device (8) to continuously rotate in one and the same direction of rotation (H) about a threaded part ( 66) and which thereby engages in threads (71, 72) in the threaded part (66), that the threaded part (66) is movable in its longitudinal direction in reciprocating movements (D) in order to impart the elongate drive means (23) its reciprocating movements, that the carrier (70) imparts to the threaded part (66) its reciprocating movements (D) by cooperating with its threads during its rotation (H) (71, 72) , and that the threaded part (66) has two threads (71, 72) with oil thread directions, which endlessly merge into each other via lower and upper transition portions (73, 74) so that the carrier (70), during its continuous rotation in one and the same direction (H), continuously imparts the threaded part ( 66) its reciprocating movements (D).