US3730122A - Salvage pontoon - Google Patents

FIG. 6 is a sectional view of a plate type attachment arm taken along

lines

66 of FIG. 3; and

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIG. 1, a load, such as a sunken ship 11, to be raised is shown as resting on the sea bottom. A

salvage pontoon

12 is attached thereto by

suitable arms

13. A deep submergence

salvage work vehicle

14 is attached to each end of

pontoon

12 for positioning thereof relative to ship 12 prior to the attachment of

arms

13 thereto.

Deep submergence vehicle

14 has an

external manipulator arm

15 which is used for attaching

arms

13 to ship 11, for moving conductor 16, and other purposes. When

pontoon

12 is positioned in cooperative relation to ship 11,

deep submergence vehicle

14 may separate therefrom and maneuver independently.

An electrical conductor 16 is lowered from the sea surface and has a

connector plug

17 secured to the distal end thereof. As will be understood by those familiar with salvage operations, plug 17 is grasped by

arm

15 and inserted into a

receptacle

18, which is mounted on

pontoon

12. In instances where a plurality of

pontoons

12 are required, a single conductor 16 may be lowered from the surface with a junction box, not shown, on the distal end thereof, in place of

connector

17. Further conductors emanating from the junction box with

connectors

17 thereon are placed in

receptacles

18 on the individual ones of the plurality of

pontoons

12.

Attachment of the deep submergence

salvage work vehicle

14, hereafter termed salvage vehicle, to salvage

pontoon

12 is accomplished by means of a suitable vacuum or

hydrostatic coupler

19. Couplers l9 cooperate with flat portions, to be more completely described herein, on each end of

salvage pontoon

12 in such a manner as to attach

salvage vehicles

14 thereto. If desired,

salvage vehicles

14 may be interconnected so that control thereof may be exercised from a single vehicle. This control interconnection may be accomplished by a fixed wire communication link within

salvage pontoon

12, or, if desired, by an acoustic wave, i.e., sonar-like, communication link through the water. Both of these arrangements may be incorporated in each salvage vehicle, one serving as a back-up system for the other, if desired. The exact nature and functioning of the control system has no direct bearing to the present invention and, since prior art systems capable of providing the communication link are well known, the selection of a suitable system is left to the choice of the skilled worker making and using the invention.

Referring now to FIG. 2, an end elevation of

pontoon

12, it may be seen that

pontoon

12 comprises a box-

like base portion

21 and a cylindrical tank-like

buoyant portion

22.

Suitable supports

23, spaced at predetermined intervals, join

base portion

21 and

buoyant portion

22. The number and location of

supports

23 are, of course, depend upon the material from which they are made and the expected loads to be borne thereby. It should be noted that the illustrated configuration is but an exemplary construction and other arrangements are possible. For example,

base portion

21 may extend upwards to join and partially enclose

buoyancy portion

22 so as to incorporate

supports

23 as integral portions thereof. These constructional details are well understood parameters of design to persons familiar with the fields of naval architecture and, quite naturally, may be varied to suit the individual circumstances of the particular requirements. For purposes of explanation, it need only be noted that the construction serves to rigidly unite the component parts of

pontoon

12 into a rigid assembly capable of withstanding the loads placed thereon.

On suitable bulk heads, to be more completely described, located at each end of cylindrical

buoyant portion

22,

coupling plates

20 are located. Coupling

plates

20 serve as attachment points for

vacuum couplers

19 and may simply be flat steel plates, if desired. However, since the vacuum seal is the means by which

pontoons

12 are moved by

salvage vehicles

14,

coupling plates

20 may be modified to promote cooperation with their mating parts. One type of modification includes a coating of the surface of

coupling plate

20 with a plastic or synthetic rubber compound to promote a watertight seal therewith by gasket means on

vacuum coupler

19. In place of coatings, or in addition thereto, the face of

plate

20 may be figured to promote a watertight seal. Such figuring is well understood in the vacuum attaching and vacuum chuck arts. The selection as between coatings, figurings and combinations of the two is regarded as a matter of design choice.

Along the center of the upper surface of

buoyant portion

22, where

receptacle

18 is located, a plurality of

suitable hatches

24 are installed.

Hatches

24 permit crew members to enter the interior of the

buoyant portion

21 for service thereof. Of course, in

operation pontoon

14 is unmanned and the hatches are secured. Since entry into the

buoyant portion

21 is infrequent, hatches 24 may be secured with threaded fasteners or other semi-permanent fastening means.

Receptacle

18 may be any multiconductor electrical connection means constructed for electrical connection in underwater environments. For example, the connector described in the aforementioned US. Pat.

filed Mar. 22, 1971, by James H. Elkins, one of the inventors of the incident invention, was especially designed for this application. However, the successful operation of

pontoon

12 does not depend on any particular electrical connector construction and, accordingly, no specific construction thereof is shown herein.

Buoyant portion

22 contains, in suitable interior compartment means, suitable, large-volume, cryogenic Dewar flask means 25. Suitable support means 26 provide secure mounting for Dewar flash means 25. A more complete explanation of this portion of the invention will be provided in connection with the description of FIG. 3, where the details of the cryogenic Dewars are more clearly shown.

Base portion

21 houses, along with other components, the ballast components of

pontoon

12. A

weighted hatch

26 has an

eye bolt

27 extending therethrough. A

suitable ballast chain

28 is secured to

eye bolt

27 and disposed within a

ballast compartment

30 within

base portion

21. As will be more completely described presently, the ejection of

hatch

26 along the direction shown by

arrow

29 drags

ballast chain

28 thereafter to cause the lightening of

pontoon

14. Although a plurality of

hatches

26 are provided, only one is shown as being deployed for purposes of illustration. In operation all are deployed simultaneously.

Ballast chain

28 is of any suitable construction to provide the necessary weight, so as to obtain the desired change of buoyancy when ejected. In a developmental embodiment of the invention standard anchor chain has proven satisfactory. The type of chain employed was twelve centimeter chain weighing 7,600 Kg per 25 meter shot. If heavier chain is required, it may be especially fashioned for this purpose and may comprise lead clad steel links, for example. Of course, if lesser weights are specified, other stock chains may be employed. The terminology ballast chain as used herein may refer to any suitable configuration of ballast weights and should not be construed as limited to the linked chain form disclosed herein. However, the restraining control means, to be described presently, limits the ballast to some unitary construction that may be made fast to a line or cable.

The attachment arms, shown generally at 13 in FIG. 1, are also carried by

base portion

21.

Attachment arms

13 are of two general types, rigid and flexible. Each type of arm is mounted on a pair of outwardly extending mounting

bosses

31. A plurality of pairs of

bosses

31 extend along each side of

base portion

21 to permit the number of arms to be selected in accordance with the particular circumstances. For purposes of simplicity of illustration, arms are shown as being attached to only one side of

base portion

21. In actuality, of course, both sides of

base portion

21 have arms attached thereto.

One type of arm is formed of a belted

chain

32. Belted

chain

32 offers the advantage of conforming to a variety of different load shapes. Also, belted

chain

32

permits fastening pontoon

14 to loads, such as ship 11, in such a fashion as to lift the load in a different orientation than it is found in. Thus, belted

chains

32 may be attached to the port and starboard sides of the deck of a wreck lying on its side so as to lift it in an upright fashion.

FIG. 2 also illustrates a

tubular arm

33 mounted on

base portion

21. Although shown as straight,

tubular arm

33 may be formed so as to fit and captively embrace irregular shapes such as specific hull shapes. At the outboard end of

arm

33, a mounting

plate

34 is hingedly attached so as to be movable to rest in surface contact with the object to be lifted at a suitable mounting point thereon. Mounting

plate

34 will be more completely described herein.

Rather than depending vertically downwardly, as in the case of belted

chain

32,

tubular arm

33 may be held outwardly from

pontoon

12 by suitable support means, such as a

chain

35, extending between

eyes

36 on the outer end of

tubular arm

33 and on

buoyancy portion

22. Provisions may also be provided, if desired, for adjusting the length of the support means and, thereby, the position of

tubular arms

33. Such a length adjustment may be provided for

chain

35 by a

turnbuckle

37. Means, not shown, may also be provided to sever or otherwise

part chain

35 to cause

arms

33 to drop from their outwardly supported position to a downwardly extending position. This arm repositioning operation may be accomplished when

salvage pontoon

14 is in the desired position with respect to the object to be lifted.

Referring now to FIG. 3, a side elevation of

salvage pontoon

12 with a portion thereof broken away for illustration purposes. However, in place of

tubular arms

33,

plate arms

38 are shown mounted on either end of

base portion

21 in

bosses

31. As previously indicated,

bosses

31 are of a standard spacing to accept a variety of attaching means to connect

pontoon

14 to the load to be raised, such as ship 1 1. In this regard, the varieties of arms shown and described herein should be regarded as only exemplary embodiments. As the number of

salvage pontoons

12 increase and they become more commonly available, it is envisioned ships plying the world waterways will carry arms or other fittings to be received and held by standard arms or attached directly to

bosses

31.

It should also be apparent that

bosses

31 themselves, are subject to modification. Of course, other attachment means may be installed on

base portion

21 to receive the standard attachment arms. Accordingly, as experience is gained in the use of the pontoon of the invention, skilled workers may make desired modifications to the invention without departing from the scope thereof.

Buoyant portion

22 has a

cylindrical hull portion

39 closed at each end with

end bulkheads

41. As previously noted,

coupling plates

20 are located on

bulkheads

41. As shown,

salvage pontoon

12 is symmetrical and both end

bulkheads

41 are of the same shape. However, if desired, they could be configured to provide a more hydrodynamically shaped bow at one end to enhance surface towing of

pontoon

12 so as to promote surface transport thereof to the site of the salvage as well as hasten the deployment thereof.

In either construction, symmetrical or unsymmetrical,

bulkheads

41 cooperate with

hull portion

39 to form a stressed enclosure for the cryogenic gas supplies and other components to be kept dry and at regulated pressures.

Hull portion

39 is made of sheet steel with reinforcement provided by

suitable ribs

42 spaced at predetermined intervals therealong.

Ribs

42 are of 1 section steel although other structural shapes may be used, if desired.

Two

interior bulkheads

44, one shown, divide the interior of buoyant portion into three compartments.

Aside from their portioning function,

bulkheads

44 add compressional strength and torsional rigidity to the structure of

buoyant portion

21. Bulkheads 44 are substantially the same as the exterior and

bulkheads

41 with the obvious exception that they have no coupling plate installed thereon. Bulkheads 44 are spaced in such a predetermined fashion that the end compartments defined thereby are of smaller volume than the center compartment located therebetween.

A cryogenic Dewar is located in each of the end compartments. Although there are other components of the salvage pontoon system located therein, the size of

Dewar

25 primarily determines the placement of

bulkheads

44 and, therefore, the relative sizes of the compartments.

Cryogenic Dewar

25 is held in place against the forces resulting from the movement of

pontoon

12 by a suitable support means 45.

Dewar

25 and its support means 45 are conventional state-of-the-art components which are well known in the cryogenic engineering arts. Since several types thereof are available, the choice between them is left to the proficient artisan.

Each

Dewar

25 is of sufficient size to exhaust the central compartment of water. The two

Dewars

25 have, therefore, the combined capacity to make two salvage lifts before requiring replenishment. Dewars of such large capacity require pressure regulation to perform at deep ocean depths. Pressure regulation is provided by

suitable pressure regulators

46 which, like

Dewar

25, is of conventional state-of-the-art construction. The boil-off gas is vented to the outside by

regulator

46 by means of a conduit 47.

The center compartment of

buoyant portion

22, located between

bulkheads

44, comprises the variable buoyancy portion of

pontoon

12. Water, which fills the compartment during periods of negative buoyancy and partially fills the compartment during periods of neutral or controlled buoyancy, is pressure equalized by means of a standpipe 48. As may be seen in FIG. 3, standpipe 48 communicates between the interior of the central compartment and the outside ambient water.

Standpipe 48 is of an inverted U shape having open ends. The interior opening thereof is near the deck, or lower surface, of the central compartment. The interior opening is in one end of standpipe 48. The other end thereof is somewhat longer and penetrates the

cylindrical hull portion

39 to open on the exterior of

buoyant portion

39. Standpipe 48 is mounted by means of

triangular braces

49 which, in addition to their supporting function, brace standpipe against flexure caused by movement of water at high pressures therethrough.

The transfer of gas from

Dewar

25 to the central compartment is initiated by response to an electrical command signal from the surface transmitted via electrical conductor 16, electrical connector 17 (FIG. 1) and

receptacle

18. The internal wiring of

pontoon

12 is not shown since it is not necessary for the understanding of the invention and since, even though complex and extensive, such wiring systems are well understood and within the skill of one versed in the marine engineering arts. The draining of the liquified gas from

Dewar

25 is controlled by cryogenic

control valve apparatus

51.

Rather than supply gas directly to the buoyancy compartment,

valve

51 routes the gas, via

conduit

52, to a

heat exchanger

53. As will be well understood by those familiar with liquified gases, the change of state from a liquid to a gas is accompanied by a thermal exchange. If an attempt is made to effect the exchange directly there would be danger that the water surrounding the discharge end of the conduit would freeze to create a blockage thereat. Such blockage, coupled with the rapid rise of pressure, might result in explosive forces being generated within the system. The presence of

heat exchanger

53 in the system lessens this possibility.

Heat exchanger

53 is located within

base portion

21 and is in thermal contact therewith and with the surrounding water. The gaseous output from

heat exchanger

53 is transferred to the interior of

buoyant portion

22 by means of

conduit

54 connected therebetween. Of course, some thermal transfer occurs as the gas passes through

conduits

52 and 54. The temperature of the gas is raised until it enters the central compartment, where its temperature is above the freezing point of sea water.

The gas entering

buoyant portion

22 displaces the water therein through standpipe 48 in the well understood fashion common within the submarine engineering discipline. The ejection of the water therefrom and its replacement with gas from

Dewar

25, of course, results in a change of buoyancy for

pontoon

12.

Before

pontoon

12 is attached to the object to be raised, its buoyancy is controlled to closely approximate neutral buoyancy by

control valve

51. After

pontoon

12 is attached, the ballast is jettisoned and

valve

51 controls the buoyancy to provide positive buoyancy so as to raise the object to the surface.

Control valve

51 is actuated from the surface, via the previously described control link, to accomplish the desired changes in degree of buoyancy regulation.

As previously described,

ballast chain

28 is jettisoned by releasing

hatch

26 to which it is attached by

eye bolt

27.

Hatch

26 is held in place in

base portion

21 by means of latch bolts 55 which engage cooperating

holes

56 in the margin thereof.

Latch bolts

57 are explosively severed upon receipt of electrical .command signals from the surface, as obviously described. As the

ballast chain

58 pays out, the buoyancy of

pontoon

12 and its attached load alters to become positive so as to start to ascend.

As is well understood, an uncontrolled ascent is not desired. To provide a control for the rate at which pontoon 12

surfaces ballast chain

28 is connected to suitable restraining cable means 57, see FIG. 4, by suitable attaching

tackle

58. Of course, restraining

cable

57 is attached to

base portion

21 of salvage pontoon l2 and is of sufficient length to reach the surface, or to the height from the bottom to which it is desired to lift the salvaged object. However, rather than being payed out continuously or at one time, restraining

cable

57 is payed out in predetermined lengths so as to permit

pontoon

12 and its attached load to be raised in controlled increments. To accomplish this end, said predetermined lengths of restraining

cable

57 are wound into a plurality of

loops

59. Each

loop

59 is bridged by a short length of

cable

61 with an

explosive cutter

62 positioned in cooperative relation thereto.

Cable

61 provides strain isolation for its associated

loop

59. Firing each

cutter

62 severs

short cable

61 and thereby permits the

particular loop

59 associated therewith to be payed out.

Referring to FIG. 5, restraining

cable

57 has the

loops

59 placed inside a

frangible tube

63. This constructional convenience permits the storage of a considerable number of

loops

59 without entanglement.

Loops

59 are adhesively secured to the inner surface and

explosive cutters

62 are positioned along the outer surface and extend the walls of

tube

63. The buoyancy force of pontoon l2 extracts

cable

57 pulling it free of

tube

63.

Tube

63 may break away as

cable

57 is withdrawn therefrom. Instead of a single tube with

circular coils

59, a double tube arrangement with figureeight shaped coils, not shown, may be used, if desired. Such an alternate arrangement requires a smaller tube length for a given length of restraining

cable

57.

Tubes

63 are located within

base portion

21 and

cutters

62 are electrically fired in sequence on command from the surface.

Referring to FIG. 6, a sectional view of

plate arm

38 taken along line 6-6 of FIG. 3, one will see that the structure is built on a

T section beam

64. A plurality of threaded holes in the flange, or base plate portion, of

beam

64 accept explosive driven

stud assemblies

65 therein. Explosive driven

stud assemblies

65 are conventional state-of-the-art units.

Stud assemblies

65 are fired electrically from the surface via the aforedescribed command link.

Conductors

66 on

arm

38 complete the circuit to the individual stud assemblies.

Gaskets

67 are located along the object engaging surface of

arm

38 form watertight contact with the object to be lifted when

arm

38 is resting thereon.

Gaskets

67 together with

arm

38 form a vacuum gripping surface with the object to be lifted in the same manner as

vehicle

14 attaches

pontoon

12 thereto. A source of vacuum connected thereto by conduit means, not shown, causes

arm

38 to be drawn into contact with the object to be lifted. This contact enhances the penetration and effectiveness of explosive driven

studs

65.

Referring to FIG. 7, the distal end of

tubular arm

33, as illustrated in FIG. 2, is shown. As may be seen, mounting

plate

34 is attached to

arm

33 by means of a

hinge

68. Like

plate arm

38, previously described, mounting

plate

34 has a plurality of explosive driven

studs

65 mounted thereon. To increase the area of

attachment ears

69 may extend outwardly from

plate

34 with

studs

65 mounted thereon.

Chain belt arms

32 may also carry mounting

plates

31 at the distal ends thereof.

Salvage pontoon

12 is first transported to the salvage cite. This may be accomplished either with surface towing techniques or as deck cargo on a suitable salvage vessel or barge. When at the salvage cite and in the water,

salvage work vehicles

14 take

salvage pontoon

12 in tow and transport it to the wreck, or other object, to be raised thereby. Attachment of

work vehicle

14 to

pontoon

12 is made by a vacuum coupler attached to

coupling plate

26. During this transportation time,

valve mechanism

51 regulates the buoyancy of

pontoon

12 to assure that it is neutrally buoyant.

When

pontoon

12 is in place with respect to the wreck,

work vehicle

14 detaches itself therefrom and positions the lifting arms in place with respect to the wreck. The precise operations performed depend in large measure on the particular type of arm that is fitted on

salvage pontoon

12.

If the belted

chain arms

32 are fitted, the crew in

salvage work vehicle

14 move the end thereof into cooperative arrangement with ship 11, or other object to be raised. In some instances, salvage

pontoon

12 may be placed alongside ship 11 and connections of belted chain arms made thereto in such a manner that ship 11 is raised in a different attitude than it occupies on the bottom. The particular manipulative steps depend upon the precise nature of the fastenings on

chain belt arms

33. If mechanical fittings are employed, the connections are made by the use of

manipulator

15. If explosive driven studs are employed, the crew of

work vehicle

14 place the terminating pad on which

studs

65 are mounted in the desired position to which attachment is to be made. This mounting pad, not illustrated in the drawings, may be the same as mounting

plate

34 used on

tubular arm

33.

If the inflexible

tubular arms

33 are used on

salvage pontoon

12, the degree of manipulation by the crew of work vehicle is correspondingly less. In such instances, the work vehicle crew releases

arms

33 from the supporting

chains

35 to cause them to come to rest on ship 11.

Plates

34 are hinged into operating position by use of

manipulator

15 when

tubular arms

33 are in place.

A similar positioning procedure is employed if

plate arms

38 are mounted on

salvage pontoon

12. When

arms

38 are equipped with the vacuum attachment means, the crew of

work vehicle

14 make the necessary vacuum connections thereto to draw

arms

38 tightly into contact with ship 11 prior to the detonation of explosive driven

studs

65.

When

pontoon

12 is in place and attached to ship 1 1, electrical conductor 16 is lowered from the surface and

connector

17, attached thereto, is placed in

receptacle

18. In instances where

plural pontoons

12 are placed on ship 11, conductor 16 may terminate in a junction box and a plurality of short cables each with a

connector

17 on the end of each thereof. When

plug

17 is in

receptacle

18, command of

salvage pontoon

12 is exercised from the surface.

When the particular arms in use are in position and the command link to the surface is established,

explosive studs

65 are fired to firmly attach

pontoon

12 to ship 11. Ballast is then jettisoned by detonating latch bolts 55 which cause hatches 26 to be expelled dragging

ballast chain

28 therebehind.

Work vehicles

14 may assist in this operation to assure that hatches 26 and the ballast chain attached thereto are free of ship 11 as well as

pontoon

12. In some embodiments it may be desirable to route

ballast chains

28 through

tubular arms

33 with

hatches

26 at the outboard ends thereof.

When

pontoon

12 is unburdened of ballast,

valve

51 regulates the buoyancy of pontoon l2 and attached ship 11 to be positive. Having positive buoyancy, pontoon l2 rises to the level permitted by restraining

cable

57. Ship 11, being attached thereto, rises with

pontoon

12. When at the height permitted by restraining

cable

57

valve

51 readjusts the buoyancy of

pontoon

12. If

plural pontoons are used, the trim or attitude of the ship 11 and

pontoon

12 combination is adjusted at this time by regulating the relative buoyancy of the several pontoons 11. I

When pontoon l2 and ship 11 have been stabilized in the desired attitude, an

explosive cutter

61 is detonated to release a

loop

59 of restraining

cable

57 to allow

pontoon

12 together with ship 11 to rise another predetermined increment. This process is repeated until

pontoon

12 has raised ship 11 to the surface or other desired working level.