Underwater excavation apparatus

Information

  • Patent Grant
  • 6430848
  • Patent Number
    6,430,848
  • Date Filed
    Thursday, August 12, 1999
    25 years ago
  • Date Issued
    Tuesday, August 13, 2002
    22 years ago
  • CPC
  • US Classifications
    Field of Search
    • US
    • 037 317
    • 037 323
    • 037 327
    • 037 195
    • 037 331
    • 037 330
    • 037 343
    • 037 307
    • 405 73
    • 405 163
    • 405 226
    • 415 1999
    • 415 80
    • 415 81
    • 416 124
    • 416 128
    • 416 129
  • International Classifications
    • E02F388
Abstract
An improved underwater excavation apparatus achieves efficiency and control of movement through provision of a hollow body having at least one inlet and at least one outlet, at least one pair of impellers coaxially displaced one from the other and rotatably mounted in the hollow body, and a mechanism for driving the impellers in contrary rotating directions. The underwater excavation apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use. The excavation apparatus may, therefore, be substantially “T” or “Y” shaped. The mechanism for driving the impellers may include at least one drilling motor.
Description




BACKGROUND OF THE INVENTION




This invention relates to an improved excavation apparatus, and in particular to an improved underwater excavation apparatus.




Underwater excavation apparatus are known, eg, from GB 2 240 568 (CONSORTIUM RESOURCE et al). In that disclosure there is described. an underwater excavation apparatus comprising a hollow body with an inlet to receive water and an outlet for discharge of water. A propeller is rotatably mounted in the hollow body to draw water through the inlet and deliver a flow 6f water through the outlet. Water jets on the propeller tips rotate the propeller when water is supplied to the jets.




Such rotation causes water to be drawn into the body through the inlet and expelled from the body as a flow through the outlet. The flow can be used to displace material on the seabed.




Known prior art underwater excavation apparatus suffer from a number of problems/disadvantages, for example:




(a) Low energy efficiency due to e.g. hydrodynamic limitations of fluid jets, thus requiring extremely large and power hungry pumps to drive the system);




(b) tendency of apparatus to rotate in reaction to rotation of the propeller;




(c) difficulty in steering and positioning of the apparatus.




SUMMARY OF THE INVENTION




It is an object of at least some of the aspects of the present invention to seek to obviate or mitigate one or more of the aforementioned problems in the prior art.




According to a first aspect of the present invention there is provided an underwater excavation apparatus comprising a hollow body having at least one inlet and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body and means for driving the impellers.




Advantageously, the driving means cause the impellers to be driven in contrary rotating directions, in use.




The at least one inlet may be inclined at an angle to an axis along which the at least one outlet is provided.




Preferably, there is provided at least one pair of inlets.




Preferably, the at least one pair of inlets are substantially symmetrically disposed around an axis extending from the outlet.




In one embodiment the underwater excavation apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use. In this case, the excavation apparatus is, therefore, substantially “T” shaped in profile.




In an alternative embodiment the underwater excavation apparatus comprises a pair of inlets communicating with a single outlet, the inlets being substantially symmetrically disposed around an axis extending from the outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use. In this case, the excavation apparatus is, therefore, substantially “Y” shaped in profile.




Advantageously, the outlets are each spaced/inclined substantially 45° from the axis extending from the outlet.




At least one impeller may be provided within/adjacent each inlet.




The means for driving the/each impeller(s) may include at least one drilling motor.




The at least one drilling motor may comprise a stator and a rotor rotatably mounted in the stator, the stator being provided with a rod recess and an exhaust port, the rotor being provided with a rotor channel and at least one channel for conducting motive fluid from the rotor channel to a chamber between the rotor and the stator, the rod recess being provided with a rod which, in use, forms a seal between the stator and the rotor.




Although not essential it is highly desirable that the rotor be provided with a seal for engagement with the stator.




Preferably, the seal is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal, copper alloys and stainless steel.




Advantageously, the rod is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal, copper alloys and stainless steel.




Preferably, the stator is provided with two rod recesses which are disposed opposite one another, and two exhaust ports which are disposed opposite one another, each of the rod recesses being provided with a respective rod, the rotor having two seals which are disposed opposite one another.




The drilling motor may advantageously comprise two drilling motors arranged with their respective rotors connected together each motor comprising a stator and a rotor rotatably mounted in the stator, the stator being provided with a rod recess and an exhaust port, the rotor being provided with a rotor channel and at least one channel for conducting motive fluid from the rotor channel to a chamber between the rotor and the stator, the rod recess being provided with a rod which, in use, forms a seal between the stator and the rotor.




Preferably, the drilling motors are connected in parallel, although they could be connected in series if desired.




Advantageously, the drilling motors are arranged so that, in use, one drilling motor operates out of phase with the other. Thus, in a preferred embodiment each drilling motor has two chambers and the chambers in the first drilling motor are 90° out of phase with the chambers in the second drilling motor. Similarly, in an embodiment in which each drilling motor has four chambers, the chambers in the first drilling motor would preferably be 45° out of phase with the chambers on the second drilling motor. This arrangement helps ensure a smooth power output and inhibits stalling.




Alternatively, the at least one drilling motor may be a “Moineau”, hydraulic or a suitably adapted electric motor.




The impellers may be driven by means of a gearbox or by exploitation of the opposing reactive torque on a drive body of the motor.




When the reactive torque upon the motor body is utilised, at least one impeller may be connected to an output shaft of said motor, while at least one other impeller may be connected to the motor body.




Alternatively the impellers may be driven by a pair of motors operating in opposite directions. In such case said motors and impellers are balanced and equal.




The underwater excavation apparatus may further comprise an agitator device having mechanical disturbance means and fluid flow disturbance means.




The underwater excavation apparatus may, in use, be suspended from a surface vessel or mounted upon a sled of the type currently known for use in subsea excavation operations.




According to a second aspect of the present invention there is provided an underwater apparatus comprising a hollow body having a pair of inlets communicating with an outlet, at least one pair of impellers rotatably mounted in the hollow body and means for driving the impellers, the inlets being substantially symmetrically disposed around an axis extending from the outlet, wherein the inlets are not horizontally opposed to one another.











BRIEF DESCRIPTION OF THE DRAWINGS




Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings, in which:





FIG. 1

shows a cross-sectional side view of a first embodiment of an excavation apparatus according to the present invention;





FIG. 2

shows a longitudinal cross-sectional view of one embodiment of a drilling apparatus for use in the excavation apparatus in

FIG. 1

according to the present invention;





FIGS. 3A-3D

are cross-sectional views along line A—A of

FIG. 2

showing a rotor of the motor in four different positions; and





FIGS. 4A-4D

are cross-sectional views along line B—B of

FIG. 2

showing the rotor in four different positions.





FIG. 5

shows a cross-sectional side view of a second embodiment of an excavation apparatus according to the present invention;





FIG. 6

shows a cross-sectional side view of a third embodiment of an excavation apparatus according to the present invention.











DETAILED DESCRIPTION OF INVENTION




Referring to

FIG. 1

, there is shown a first embodiment of an underwater excavation apparatus


300




a


according to the present invention. The apparatus


300




a


comprises a hollow body


370




a


formed from a pair of horizontally opposed inlet ducts


371




a


and an outlet duct


373




a


, a drive motor


310




a


and a pair of impellers


335




a


,


340




a.






The apparatus


300




a


is further provided with deflection baffles


302




a


within the hollow body


370




a


, suspension brackets


306




a


to enable the apparatus


300




a


to be suspended from a surface vessel, guide vanes


386




a


to regulate the flow of fluid past the impellers


335




a


,


340




a


, and safety grids


385




a


to seek to prevent the ingress of solid matter which may damage the impellers


335




a


,


340




a.






In this first embodiment, the drive motor


310




a


is provided along an axis common to the horizontally opposed inlet ducts


371




a


and impellers


335




a


,


340




a


. An output shaft


330




a


of the motor


310




a


is connected to a first impeller


335




a


while the second impeller


340




a


is attached to a shaft


342




a


connected via a swivel


325




a


to an outer housing of the drive motor


310




a.






In use, motive fluid is supplied to the motor


310




a


via fluid inlet


308




a


which in turn causes the output shaft


330




a


and impeller


335




a


to rotate. Reactive torque from this rotation causes the outer housing of the drive motor


310




a


to rotate in a direction opposite to that of the output shaft


330




a


. This in turn results in the rotation of the second impeller


340




a


. The impellers


335




a


,


340




a


are configured such that, despite rotating in opposite directions, they each provide an equal flow rate of water into the hollow body


370




a


. Water drawn into the hollow body


370




a


thus is directed via the deflection baffles


302




a


through the outlet duct


373




a


and towards the seabed


400




a.






The shaft


342




a


and swivel


325




a


may, in an alternative embodiment, be replaced by a second motor which directly drives the impeller


340




a


, as hereinbefore described with reference to FIG.


5


.




The excavation device


300




a


may be suspended, for example, from the bow or stern of a surface vessel, or through a moonpool of a dedicated subsea operations vessel.




In an alternative embodiment the device


300




a


may be provided upon a sled (not shown) of the type currently used for subsea operations. The excavation apparatus


300




a


may further be provided with an agitator device (not shown) having mechanical disturbance means and fluid flow disturbance means.




In an advantageous embodiment the motor


310


comprises a drilling motor, such as that disclosed in WO95/19488, the content of which is incorporated herein by reference.




The drilling motor


310


may comprise a first motor


20


and a second motor


50


.




The first motor


20


comprises a stator


21


and a rotor


23


. A top portion


22


of the rotor


23


extends through an upper bearing assembly


24


which comprises a thrust bearing


26


and seals


25


.




Motive fluid, e.g. water, drilling mud or gas under pressure, flows down through a central sub channel


12


into a central rotor channel


27


, and then out through rotor flow channels


28


into action chambers


31


and


32


.




Following a motor power stroke, the motive fluid flows through exhaust ports


33


in stator


21


, and then downwardly through an annular channel circumjacent the stator


21


and flow channels


35


in a lower bearing assembly


34


. A portion


36


of the rotor


23


extends through the lower bearing assembly


34


which comprises a thrust bearing


37


and seals


38


.




The ends of the stator


21


are castellated and the castellations engage in recesses in the respective upper bearing assembly


24


and lower bearing assembly


34


respectively to inhibit rotation of the stator


21


. The upper bearing assembly


24


and lower bearing assembly


34


are a tight fit in an outer tubular member


14


and are held against rotation by compression between threaded sleeves


16


and


84


.




A splined union


39


joins a splined end of the rotor


23


to a splined end of a rotor


53


of the second motor


50


. The second motor


50


has a stator


51


.




A top portion


52


of the rotor


53


extends through an upper bearing assembly


54


. Seals


55


are disposed between the upper bearing assembly


54


and the exterior of the top portion


52


of the rotor


53


. The rotor


53


moves on thrust bearings


56


with respect to the upper bearing assembly


54


.




Motive fluid flows into a central rotor channel


57


from the central rotor channel


27


and then out through rotor flow channels


58


into action chambers


61


and


62


. Following a motor power stroke, the motive fluid flows through exhaust ports


63


in stator


51


, and then downwardly through an annular channel circumjacent the stator


51


and flow channels


65


in a lower bearing assembly


64


. A portion


66


of the rotor


53


extends through a lower bearing assembly


64


. The rotor


53


moves on thrust bearings


67


with respect to the lower bearing assembly


64


and seals


68


seal the rotor-bearing assembly interface. Also motive fluid which flowed through the flow channels


35


in the lower bearing assembly


34


, flows downwardly through channels


79


in the upper bearing assembly


54


, past stator


51


and through flow channels


65


in the lower bearing assembly


64


.




The upper bearing assembly


54


and lower bearing assembly


64


are a tight fit in an outer tubular member


18


and are held against rotation by compression between threaded sleeve


84


and a lower threaded sleeve (not shown).





FIGS. 2A-2D

and


3


A-


3


D depict a typical cycle for the first and second motors


20


and


50


respectively, and show the status of the two motors with respect to each other at various times in the cycle. For example,

FIG. 2C

shows an exhaust period for the first motor


20


while

FIG. 3C

, at that same moment, shows a power period for the second motor


50


.




As shown in

FIG. 2A

, motive fluid flowing through the rotor flow channels


28


enters the action chambers


31


and


32


. Due to the geometry of the chambers (as discussed below) and the resultant forces, the motive fluid moves the rotor in a clockwise direction as seen in FIG.


2


B. The action chamber


31


is sealed at one end by a rolling vane rod


71


which abuts an exterior surface


72


of the rotor


23


and a portion


74


of a rod recess


75


.




At the other end of the action chamber


31


, a seal


76


on a lobe


77


of the rotor


23


sealingly abuts an interior surface of the stator


21


.




As shown in

FIG. 2B

, the rotor


23


has moved to a point near the end of a power period.




As shown in

FIG. 2C

, motive fluid starts exhausting at this point in the motor cycle through the exhaust ports


33


.




As shown in

FIG. 2D

, the rolling vane rods


71


and seals


76


have sealed off the action chambers and motive fluids flowing thereinto will rotate the rotor


23


until the seals


76


again move past the exhaust ports


33


.




The second motor


50


operates as does the first motor


20


; but, as preferred, and as shown in

FIGS. 3A-3D

, the two motors are out of phase by 90° so that as one motor is exhausting motive fluid the other is providing power.




The seals


76


are, in one embodiment, made of polyethylethylketone (PEEK). The rolling vane rods


71


are also made from PEEK. The rotors (


23


,


25


) and stators (


21


,


51


) are preferably made from corrosion resistant materials such as stainless steel.




When a seal


76


in the first motor


20


rotates past an exhaust port


33


, the motive fluid that caused the turning exits and flows downward, then through the channels


79


, past the exhaust ports


63


and the flow channels


65


.




It should be appreciated that although in the disclosed embodiment the drilling motor


310


comprises two motors


20


,


50


, with suitable adaptation, the drilling motor


310


may comprise only one motor


20


or


50


.




Referring now to

FIG. 5

, there is shown a second embodiment of an underwater excavation apparatus


300




b


according to the present invention. Like parts of the apparatus


300




a


are identified by numerals used to identify parts of the apparatus


300




a


of

FIG. 1

, except subscripted with “b” rather than “a”.




The apparatus


300




b


differs from the apparatus


300




a


in that the shaft


342




a


and swivel


325




a


are replaced by a second motor


310





b


and a T-coupling


326




b


. Thus in this embodiment the impellers


335




b


,


340




b


are driven by respective motors


310




b


,


310





b


. In use, motive fluid is supplied to motors


310




b


,


310





b


via fluid inlet


308




b


and T-coupling


326




b.






Referring now to

FIG. 6

, there is shown a second embodiment of an underwater excavation apparatus


300




c


according to the present invention. Like parts of the apparatus


300




b


are identified by numerals used to identify parts of the apparatus


300




b


of

FIG. 5

, except subscripted with “c” rather than “b”.




The apparatus


300




c


differs from the apparatus


300




b


in that whereas in apparatus


300




b


the inlets


371




b


are horizontally opposed, in apparatus


300




c


the inlets are substantially symmetrically disposed around an axis extending from outlet


373




c


, such that the apparatus


300




c


is substantially “Y” shaped. In this embodiment there is, therefore, provided a Y-coupling


326




c.






The embodiments of the invention hereinbefore described are given by way of example only, and are not meant to limit the scope of the invention in any way. It should be particularly appreciated that the drilling motor


310


is suitable for use in any of the disclosed embodiments.



Claims
  • 1. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the driving means cause the impellers to be driven in contrary rotating directions.
  • 2. An underwater excavation apparatus as claimed in claim 1, wherein there is provided one pair of inlets.
  • 3. An underwater excavation apparatus as claim in claim 1, wherein the apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “T” shaped in profile.
  • 4. An underwater excavation apparatus as claimed in claim 1, wherein the apparatus comprises a pair of inlets communicating with a single outlet, the inlets being substantially symmetrically disposed around an axis extending from the outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “Y” shaped in profile.
  • 5. An underwater excavation apparatus as claimed in claim 2, wherein the apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “T” shaped in profile.
  • 6. An underwater excavation apparatus as claimed in claim 2, wherein the means for driving the impellers includes at least one drilling motor.
  • 7. An underwater excavation apparatus as claimed in claim 1, wherein one of the impellers is provided within one of the inlets and another of the impellers is provided within another of the inlets.
  • 8. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the means for driving the impellers includes at least one drilling motor.
  • 9. An underwater excavation apparatus as claimed in claim 8, wherein the at least one drilling motor comprises a stator and a rotor rotatably mounted in the stator, the stator being provided with a rod recess and an exhaust port, the rotor being provided with a rotor channel and at least one channel, for conducting motive fluid from the rotor channel to a chamber between the rotor and the stator, the rod recess being provided with a rod which, in use, forms a seal between the stator and the rotor.
  • 10. An underwater excavation apparatus as claimed in claim 9, wherein the rotor is provided with a seal for engagement with the stator.
  • 11. An underwater excavation apparatus as claim in claim 10, wherein the seal is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal, copper alloys and stainless steel.
  • 12. An underwater excavation apparatus as claimed in claim 9, wherein the rod is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal copper alloys and stainless steel.
  • 13. An underwater excavation apparatus as claimed in claim 9, wherein the stator is provided with two rod recesses which are disposed opposite one another, and two exhaust ports which are disposed opposite one another, each of the rod recesses being provided with a respective rod, the rotor having two seals which are disposed opposite one another.
  • 14. An underwater excavation apparatus as claimed in claim 10, wherein the rod is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal, copper alloys and stainless steel.
  • 15. An underwater excavation apparatus as claimed in claim 10, wherein the stator is provided with two rod recesses which are disposed opposite one another, and two exhaust ports which are disposed opposite one another, each of the rod recesses being provided with a respective rod, the rotor having two seals which are disposed opposite one another.
  • 16. An underwater excavation apparatus as claimed in claim 11, wherein the rod is made from a material selected from the group consisting of plastics materials, polyethylethylketone, metal, copper alloys and stainless steel.
  • 17. An underwater excavation apparatus as claimed in claim 11, wherein the stator is provided with two rod recesses which are disposed opposite one another, and two exhaust ports which are disposed opposite one another, each of the rod recesses being provided with a respective rod, the rotor having two seals which are disposed opposite one another.
  • 18. An underwater excavation apparatus as claimed in claim 12, wherein the stator is provided with two rod recesses which are disposed opposite one another, and two exhaust ports which are disposed opposite one another, each of the rod recesses being provided with a respective rod, the rotor having two seals which are disposed opposite one another.
  • 19. An underwater excavation apparatus as claimed in claim 8, wherein the at least one drilling motor comprises two drilling motors arranged with their respective rotors connected together each motor comprising a stator and a rotor rotatably mounted in the stator, the stator being provided with a rod recess and an exhaust port, the rotor being provided with a rotor channel and at least one channel for conducting motive fluid from the rotor channel to a chamber between the rotor and the stator, the rod recess being provided with a rod which, in use, forms a seal between the stator and the rotor.
  • 20. An underwater excavation apparatus as claimed in claim 19, wherein the drilling motors are connected in parallel or in series.
  • 21. An underwater excavation apparatus as claimed in claim 19, wherein the drilling motors are arranged so that, in use, one drilling motor operates out of phase with the other.
  • 22. An underwater excavation apparatus as claimed in claim 20, wherein the drilling motors are arranged so that, in use, one drilling motor operates out of phase with the other.
  • 23. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “T” shaped in profile.
  • 24. An underwater excavation apparatus as claimed in claim 23, wherein the means for driving the impellers includes at least one drilling motor.
  • 25. An underwater excavation apparatus as claimed in claim 23, wherein at least one impeller is provided within each outlet.
  • 26. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein one of the impellers is provided within one of the inlets and another of the impellers is provided within another of the inlets.
  • 27. An underwater excavation apparatus as claimed in claim 26, wherein there is provided one pair of inlets.
  • 28. An underwater excavation apparatus as claimed in claim 26, wherein the apparatus comprises a pair of horizontally opposed inlets communicating with a single outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “T” shaped in profile.
  • 29. An underwater excavation apparatus as claimed in claim 26, wherein the apparatus comprises a pair of inlets communicating with a single outlet, the inlets being substantially symmetrically disposed around an axis extending from the outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “Y” shaped in profile.
  • 30. An underwater excavation apparatus as claimed in claim 26, wherein the means for driving the impellers includes at least one drilling motor.
  • 31. An underwater excavation apparatus as claimed in claim 26, wherein the means for driving the impellers includes at least one drilling motor.
  • 32. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the apparatus comprises a pair of inlets communicating with a single outlet, the inlets being substantially symmetrically disposed around an axis extending from the outlet, the outlet being disposed vertically downwards substantially midway between the two inlets, in use, such that the excavation apparatus is substantially “Y” shaped in profile.
  • 33. An underwater excavation apparatus as claimed in claim 32, wherein the means for driving the impellers includes at least one drilling motor.
  • 34. An underwater excavation apparatus as claimed in claim 32, wherein the inlets are each inclined substantially 45° from the axis extending from the outlet.
  • 35. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the impellers are driven by means of a gearbox.
  • 36. An underwater excavation apparatus as claimed in claim 35, wherein the reactive torque upon the said drive body is utilized, at least one impeller is connected to an output shaft of said motor, while at least one other impeller is connected to the said drive body.
  • 37. An underwater excavation apparatus comprising a hollow body having one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, wherein the means for driving the impellers includes at least one drilling motor.
  • 38. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the impellers are driven by a pair of motors operating in opposite directions.
  • 39. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the underwater excavation apparatus further comprises an agitator device having mechanical disturbance means and fluid flow disturbance means.
  • 40. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein in use the underwater excavation apparatus is suspended from a surface vessel or mounted upon a sled.
  • 41. An underwater excavation apparatus comprising a hollow body having at least one pair of inlets and at least one outlet, at least one pair of impellers rotatably mounted in the hollow body, and means for driving the impellers, wherein the pair of inlets are substantially symmetrically disposed around an axis extending from the at least one outlet, and wherein the impellers are driven by means of exploitation of the opposing reactive torque on a drive body of at least one motor.
PCT Information
Filing Document Filing Date Country Kind
PCT/GB96/03148 WO 00
Publishing Document Publishing Date Country Kind
WO98/27286 6/25/1998 WO A
US Referenced Citations (7)
Number Name Date Kind
3235232 Conover Feb 1966 A
4914841 Weinrib Apr 1990 A
4957392 Bailard Sep 1990 A
5607289 Sills Mar 1997 A
5833444 Harris et al. Nov 1998 A
6022173 Saxon Feb 2000 A
6053663 Dikken et al. Apr 2000 A
Foreign Referenced Citations (4)
Number Date Country
0 328 198 Aug 1989 EP
2 240 568 Aug 1991 GB
2 297 777 Aug 1996 GB
2 302 348 Jan 1997 GB