NO137144B - SUBMISSIBLE DEVICE FOR USE WHEN STORING METAL OBJECTS UNDER WATER - Google Patents

Description

The present invention relates to a submersible device

for use in salvaging metal objects underwater, comprising a housing open at one end, a compressed thermite mixture within the housing, means for igniting the thermite mixture and lofting means associated with the housing to enable the housing to be pulled to the surface after it is been welded to a metal object by igniting the thermite mixture.

Salvage of underwater objects is both expensive and difficult. In the most well-known methods, a diver must attach gripping means to the object to be rescued so that it can be raised to the surface. In the case of very large boats, this is often impractical, and various other techniques have been proposed for the salvage of such boats. E.g. certain plastic materials can be pumped into the vessel's hull and activated to produce a cellular mass that will attempt to lift the object to the surface as the foam displaces the water. However, this is an expensive process which also makes it necessary

with a diver, and in many cases such a progress-

way not economically sound.

In US Patent No. 3,385,250 there is shown a submersible salvage device which is magnetically attracted to an iron object and is then able to attach itself to the object by drilling and tapping a hole. However, this device is also relatively expensive and is therefore economically impractical in situations where a large number of such devices must be used due to the size of the object to be salvaged.

The present invention provides a relatively inexpensive device for use in salvaging submerged metal objects. It is an easily transportable device which, in most cases, can be attached to the surface of the object to be rescued without the assistance of a diver in a way that is completely unknown to devices of this type. In addition, the device can be used and attached very quickly and requires very little auxiliary equipment on board to be used. The invention is not only economically viable, but it also has special advantages where the time factor is important.

According to the invention, this is achieved by a device of the type mentioned at the outset, where the new and characteristic feature is that it further comprises a metal container which encloses the housing and forms an insulating air space between the inner surface of the container and the housing, means which form a watertight seal between the container and the housing, means extending around the closed surface of the housing to direct the flow of molten metal towards an enclosed area of the article after ignition of the thermite mixture, means for sealing the open end of the housing, a flux material enclosing the thermite mixture,

an incendiary powder arranged over the thermite mixture, the incendiary powder being of the type that does not emit gases after ignition, and means for igniting the incendiary powder.

Fig. 1 shows a longitudinal section through a preferred embodiment of the invention; Fig. 2A and 2B are longitudinal sections similar to fig. 1 and shows the weld formed between the housing and the surface of the metal object to be salvaged; Fig. 3 is a longitudinal section through another embodiment of the invention; and

fig. 4A, 4B and 4C schematically show the procedure for using the device shown in fig. 3.

Fig. 1 shows a surface 8 of the object to be salvaged. The device according to the invention comprises a cylindrical housing 10

made of steel and open at the top. The housing 10 comprises a rounded bottom surface 12 which transitions into a flange 13. The housing contains a thermite material 14 which is compressed to a pressure of approximately 560 kp/cm^ and a layer of similarly compressed flux material 16 which encloses the permit 14. The permit and the flux material are massaged -sive, brick-like masses when compressed to this pressure. A thin steel cylinder 17 separates the thermite 14 and the flux 16 and helps to spread the reactivity so that local overheating is reduced. An ignition wire 18 is placed over the thermite 14.

The thermite mixture 14 is a mixture of iron oxide and iron particles (commercially available as thermite) and is known to be used in welding processes. If an oxidation reaction is started (referred to as "ignition"), the aluminium, which is a strong reducing agent, will react with oxygen from the iron oxide and reduce the iron oxide to iron. The intense heat caused by the chemical reaction not only melts iron, but raises its temperature to 2388°C. Thus, the material can be used for fusion with other metal surfaces so that a strong weld is formed.

The ignition wire 18 can consist of a slightly compressed mixture of fine-particle aluminum powder and fine-particle iron oxide (Fe^O^) in a weight ratio of 3 to 7. The particle size will depend on the available current. With only a twelve volt battery, e.g. the finest commercially available particle size be used. Lighter compaction (less than 1.75 kp/cm ) is necessary to prevent porosity in the mixture and to facilitate the reaction. This preferred kindling powder is also a thermite mixture and is preferred over other kindling powders because it does not emit gases. The flux 16 which encloses the thermite mixture 14 may comprise known materials such as e.g. high cellulose welding electrode coating or H-700 arc welding flux for underwater use marketed by Hobart Brothers Company of Troy, Ohio. This flux material helps to control the flow of molten iron, isolates the molten iron from the water and further glimmers the weld between the housing and the surface 8.

A pair of igniter cables 20 (shown schematically in Fig. 1) project into the igniter powder 18. The igniter cable is of standard design and may comprise a bare nickel-chromium cable (not particularly shown), which when the cables 20 are exposed to electrical voltage, will heated to a temperature sufficient to ignite the igniter powder 18 and thereby the thermite mixture 14. A watertight seal is formed by a lid which can be made of thin steel and which is pressed down into the open end of the housing 10 with the insulated igniter cables 20 pressed between the lid 22 and the inner surface of the housing 10.

The upper part of the housing 10 and the leak 22 may comprise two pairs of openings 24 and 26 (only the opening 26 is shown) through which cable pairs 28 and 30 pass. These cables 28 and 30 are used to raise and lower the device and may be any suitable cable depending on the application. The cables are attached to a connecting link 32 which can be gripped by a suitable device on board the vessel on which the device is to be used.

The details of the device for raising and lowering the device are not part of this invention and the cable arrangement of fig. 1 is chosen mainly because it is cheap. Because the device will often not be welded to a submerged object with its longitudinal axis vertical, the cables 28 and 30 must be able to slide into the connecting link 32 so that the housing's four connection points (openings 24 and 26) are subjected to equal forces regardless of the angle at which the device has after welding.

The entire device described so far is enclosed in a metal cover 36, the bottom of which rests on the flange 13. Also for economic reasons, the cables 28 and 30 can be routed from the openings 24

and 26 down to the bottom of the cover 36. The bottom of the cover 36 may be glued to the flange 13 to provide a watertight seal between the cover and the flange and provide an air space that encloses the housing 10.

An annular counterweight 38 may be attached to the cover 36 to help maintain the seal between the cover 36 and the flange 13

when the device is submerged in water and to hold the cover down during welding when the adhesive seal will burn away.

A copper ring 40 can be attached (e.g. by means of an epoxy glue) to the bottom of the flange 13. The ring 40 holds the molten metal due to its very high thermal conductivity so that molten iron is prevented from flowing off the surface 8.

After the weld has been formed (as described below) and the cables 28 and 30 have been stretched, the cover 36 will be loosened, but this has no particular consequences. By routing the cables 28 and 30 under the cover 36, it is not necessary to arrange further watertight openings in the cover.

The device also includes a ring 40 which can be made of copper and is attached to the underside of the flange 14 to guide the molten metal towards the surface of the metal object to be salvaged.

The way in which the embodiment in fig. 1 should be used on

should be obvious from the preceding description. Preferably, the device is magnetized by exposing its ferromagnetic parts to a strong magnetic field so that it can be lowered into water by means of the cables 28 and 30 and attach itself magnetically to the ferromagnetic surface of the object 8. After the housing is in position, the cables 20 are exposed for an electric voltage, and the powder 18 is ignited by the heat developed by the nickel-chromium wire inside the powder. The igniter powder 18 ignites the thermite mixture 14 as previously described forming a molten iron bath with a temperature of 2388°C. This melted

material melts the bottom surface 12 of the housing 10 and also burns through the adjacent surface of the object 8. The extreme temperature fuses the housing 10 and the surface 8 and forms a very strong connection as shown in fig. 2A.. It is calculated, for example, that with a house of 15 cm outer diameter, the weld that is formed will be able to lift a total weight of approximately 5

ton. The entire welding process only takes about 30 seconds.

In almost all cases, a number of devices will have to be attached to the object to be salvaged. After all the necessary devices have been welded in place, the cables 28 and 30 are stretched to raise the object to the surface as shown schematically in fig.

2B.

Fig. 3 shows another embodiment of the invention. In this invention, the housing 10, the thermite 14, the flux 16, the igniter powder 18 and the seal 22 are arranged approximately as for the embodiment shown in fig. 1. The cables 28 and 30 are arranged slightly differently, but this is not important.

According to this embodiment of the invention, a large block 50 of non-metallic material such as plastic or wood is pressed into the opening of the lid 22. A first explosive device 52 is suitably attached to the bottom of the housing surface 12, and a second explosive device 54 is attached in a suitable manner to a plate 56 which is attached to the top of the block 50. If it is desirable to arrange an insulating air gap, the entire device can be enclosed in a cover similar to the cover 36 shown in fig. 1.

The purpose of the explosive device 52 is to clean the surface

which is to be welded where the metal object has no surface where a satisfactory weld can be formed due to prolonged immersion or other reasons. The purpose of the explosive device 54 is to drive the surface 12 of the housing into the metal surface of the object to be salvaged to provide a small indentation which will serve to hold the molten material from the thermite mixture. The explosive charges 52 and 54 may comprise detonating cables 56 and 58 which are fast to the vessel from which the device is used, extending the cables 20 for the incendiary powder 18. In this way

can the explosive charges 52 and 54 be activated from the fast city,

but of course any other type of control can be used for these devices.

Figures 4A, 4B and 4C show how the embodiment in fig.

3 is used to form a tight weld to a metal surface 8 which is covered with scale or other material 60 which would normally make a weld difficult. As shown in fig. 4a, the explosive charge 52 will thus clean a small surface when the device comes into contact with the material 60 so that the surface 12 of the housing can come into contact with the metal surface 8. When the device again comes into contact with the surface 8, the explosive charge 54 will drive the entire device against the metal surface 8 with a force sufficient to create a small indentation. Then the thermite mixture 14 is ignited as described above, the housing 10 is fused with the surface 8, and the device is hauled up to the surface with the help of the cables 28 and 30.

In the embodiment shown in fig. 3, the non-metallic plate 50 absorbs the shock from the explosive device 54 and also tends to keep the device in a vertical position. If necessary, the device can of course be made heavier to counteract the buoyancy of the block 50.

If the device is used to salvage bulkheads containing liquids, especially oil, there is a possibility that the oil will leak out from the bulkhead through the housing, which will no longer be liquid-tight after the thermite mixture 14 has been ignited and the weld has formed. In such cases, the entire device can therefore be covered by a mantle with a foam plastic seal and a magnet for attaching the mantle to the surface of the tanker. In the event of a leak, the oil will be trapped in the space inside the casing.

The particular construction of the illustrated embodiments has been chosen with a view to economic performance because the device can only be used once. Thus, many different endings can be created in their structure. Instead of lowering the device by means of cables used to raise the submerged object to the surface, the housings can include various fasteners to which strong hoisting cables can be attached after the weld is completed. Special fasteners can be made on the housing 10, but the illustrated construction has been shown to be usable and preferably at the moment for economic reasons. The choice of materials (including the thermite) and the size of the device will depend on the use in each individual case. Typically, the housing 10 will have an outer diameter of 15 cm and be filled with approximately 9 kg of thermite 14. Approximately 1 1/2 2 kg of flux 16 is used to form a cylindrical layer approximately 6 - 9 mm thick. Approximately 2.3 kg of lighter powder 18 can be used. The thickness of the house walls is approximately 9 mm. The explo-

see the charge 5 2 shown in fig. 3-4 may include tooth cap no.

6 with immediate detonation and 2 g of PETN explosive (from Du-

Bridge). The charge 54 may include spark cap No. 6 with 25 ms

delayed detonation and 4 g of PETN.

Claims (5)

1. Submersible device for use when salvaging metal waste stands (8) under water, comprising a housing (10) open at one end, a compressed thermite mixture (14) inside the housing, means for igniting the thermite mixture and loft means (28, 30) connected to the housing to enable pulling the housing towards the surface after it has been welded to a metal object by igniting the thermite mixture, characterized in that it further comprises a metal container (36) which encloses the housing (10) and forms an insulating air space between the inner surface of the container and the housing, means which forming a watertight seal between the container and the housing, means (40) extending around the closed end of the housing to direct the flow of molten metal towards an enclosed area of the article (8) after ignition of the thermite mixture, means (22) for sealing the open end of the housing, a flux material (16) which encloses the thermite mixture, an incendiary powder (18) arranged over the thermite mixture, the incendiary powder being of the type that does not emit gases after ignition, and means r (20) for igniting the lighter powder. 2. Device according to claim 1, characterized in that the thermite mixture (14) is compressed into the form of massive shape-resistant mass. 3. Device according to claim 2, characterized in that the thermite mixture (14) and the flux material (16.) are compressed to approx. 560 kp/cm^. 4. Device according to claim 2, characterized in that the igniter powder (18) is a second thermite mixture with a finer particle size and under less compression than the first-mentioned thermite mixture, and that said means for igniting the igniter powder comprises an ignition line (20) inside the second thermite mixture. 5. Device according to claim 4, characterized in that the closed end (12) of the housing (10) is rounded and that said means (40), which extend around the closed end of the housing, comprise a metallic ring.