AU656186B2 - Engine for performing subsea operations and devices driven by such an engine - Google Patents

Abstract

A machine for performing work at great depths utilizes the energy which is released when surrounding water masses at great hydrostatic pressure are admitted into a low pressure reservoir via a hydraulic motor (2). The machine uses a built-in low pressure reservoir (3) as a hydrostatic accumulator, the energy which is released when the surrounding fluid is admitted into the low pressure reservoir being determined by the product of the pressure difference and the internal volume of the low pressure reservoir. In a special version (Fig. 10) the machine is designed as a hydrostatic sampler which is particularly adapted for taking core samples or marine sediments on the seabed.

Description

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OPI DATE 21/12/92 APPLN. ID 16869/92 111111111 II I11111 11111111111 111111 AOJPF DATE 28/01/93 PCT NUMBER PCT/N092/00078 111111 AU9216869

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(51) International Patent Classification 5 (11) International Publication Number: WO 92/19836 E21B 7/12, 41/00, F03G 7/04 Al (43) International Publication Date: 12 November 1992 (12.11.92) (21) International Application Number: PCT/NO92/00078 (81) Designated States: AT, AT (European patent), AU, BB, BE (European patent), BF (OAPI patent), BG, BJ (OAPI (22) International Filing Date: 24 April 1992 (24.04.92) patent), BR, CA, CF (OAPI patent), CG (OAPI patent), CH, CH (European patent), CI (OAPI patent), CM (OAPI patent), CS, DE, DE (European patent), DK, Priority data: DK (European patent), ES, ES (European patent), FI, 911668 26 April 1991 (26.04.91) NO FR (European patent), GA (OAPI patent), GB, GB (Eu- 911669 26 April 1991 (26.04.91) NO ropean patent), GN (OAPI patent), GR (European patent), HU, IT (European patent), JP, KP, KR, LK, LU, LU (European patent), MC (European patent), MG, ML (71) Applicant (for all designated States except US): SELANTIC (OAPI patent), MN, MR (OAPI patent), MW, NL, NL INDUSTRIER A/S [NO/NO]; N-6740 Selje (European patent), NO, PL, RO, RU, SD, SE, SE (European patent), SN (OAPI patent), TD (OAPI patent), TG (72) Inventors; and (OAPI patent), US.

Inventors/Applicants (for US only) AARDAL, Kare [NO/ NO]; N-6740 Selje DICKSON, Phil, Howard [GB/GB]; Merrydown, Nairdwood Lane, Prestwood, Published Bucks HP16 000 KRISTOFFERSEN, Yngve With international search report.

[NO/NO]; Kloppedalsveien Ic, N-5034 Hop LI- Before the expiration of the time limit for amending the EN, Anders [NO/NO]; N-6740 Selje LIEN, Eldar claims and ti be republished in the event of the receipt of [NO/NO]; N-6766 Kjolsdalen NORDB0, Kaare amendments.

[NO/NO]; REE, Sigurd [NO/NO]; N-6740 Selje In English translation (filed in Norwegian).

(74) Agent: ONSAGERS PATENTKONTOR AS; P.O. Box 265 Sentrum, N-0103 Oslo (NO).

656186 (54) Title: ENGINE FOR PERFORMING SUBSEA OPERATIONS AND DEVICES DRIVEN BY SUCH AN ENGINE '-i i -i

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;i i! g 49 (57) Abstract A machine for performing work at great depths utilizes the energy which is released when surrounding water masses at great hydrostatic pressure are admitted into a low pressure reservoir via a hydraulic motor The machine uses a built-in low pressure reservoir as a hydrostatic accumulator, the energy which is released when the surrounding fluid is admitted into the low pressure reservoir being determined by the product of the pressure difference and the internal volume of the low pressure reservoir. In a special version (Fig. 10) the machine is designed as a hydrostatic sampler which is particularly adapted for taking core samples or marine sediments on the seabed.

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I -i C_ I 1 Machine for subsea operations The invention concerns a machine which is intended to operate at great depths by utilizing the energy which is released when surrounding water masses under great hydrostatic pressure are admitted into a low pressure reservoir via a hydraulic motor, either of the reciprocating or the rotary type.

The inventicn also concerns a hydrostatic sampler, especially for core samples of marine sediments, wherein the sampler comprises a substantially cylindrical head and a substantially cylindrical sampler section whose longitudinal axis passes approximately through the head's centre of gravity and wherein the sampler section comprises a sampler tube consisting of at least one sampler tube section.

Engines and machines powered by pressure energy deriving from i the hydrostatic pressure of a surrounding body of water are well known in prior art. For instance, US-PS No. 3 418 818 discloses a hydrostatic power source which may be used for supplying power to underwater manipulators and propelling an underwater vehicle. US-PS No. 3 412 814 discloses a hydrostatic corer driven by the pressure differential between the hydrostatic head and a vacuum chamber. US-PS No. 3 436 914 discloses a hydrostatic energy accumulator which also is intended for drivi.,g a corer and operates in a comparable manner to the foregoing, while US-PS No. 4 215 544 discloses a method of generating deepsea rotary power by means of a turbine driven by the hydrostatic pressure differential between the surrounding body of water and an evacuated sphere.

The reason behind the invention is that the supply of, e.g., hydraulic or electrical power from, a ship to a working tool on the seabed, entails increasing difficulties as the depth increases, since transmission lines or pipes become extremely expensive, heavy, difficult to handle and vulnerable.

M SUBSTITUTE SET Li:> 2 One possibility may be to have electrical power on site, stored in the form of batteries or eliminators, but this too will be extremely vulnerable in. the environment to which the tool is exposed, and from the operational safety point of view hydraulic operation will be far preferable to electrical power.

The machine according to the invention uses an integral low pressure reservoir as a "hydrostatic accumulator", the energy which is released when the surrounding liquid is admitted into the low pressure reservoir under controlled conditions being determined by the product of the pressure difference and the internal volume of the low pressure reservoir.

For example, a low pressure reservoir with an internal volume of 1 m 3 and approximately empty of gas, when lowered to a de'pth of 2000 metres (corresponding to a pressure of approximately MPa) will be capable of releasing a pressure energy from surrounding water masses of 20 x 107 Nm, or appriximately kWh. The energy thus available will increase in proportion to the water depth and in proportion to the volume of the low pressure reservoir.

The invention concerns with various different arrangements for the utilization of this energy, together with various relevant applications.

Hydrostatic samplers are used to take core samples of the sediments in deep sea reservoirs. Such core samples are of 4 great interest with regard to paleooceanography and paleoclimatology, since deep sea sediments consist mainly of deposits resulting from the biogenic activity in the water masses. Small calcareous and siliceous organisms accumulate on the seabed at a rate of approximately 1 cm in the course of 1,000 years. The fauna and flora populations in the water masses are adapted to the special temperatures and salinities which exist at any given time, and their fossil deposits therefore bear testimony to the physical properties of the N water over the ages. In the course of the 1970's it became T U 2; iliqR TITUTE SHEET ;,rl i c:-is 3 possible to transfer the paleontological information on the relative frequency of species and their preferred temperature range via a mathematical transfer function to paleotemperatures for the sea water with an accuracy of 0.50 0 C. The use of the oxygen-isotope method also provides a temperature indication as well as a measurement of the global ice volume. Used on sediment cores from deep sea reservoirs, these methods have formed the basis for major international research programmes aimed at integrating all biological information on the climatic conditions in the Quaternary Period, and particularly the global climatic changes which have taken place since the last ice age maximum approximately 20,000 years ago. In recent years this research has gained additional relevance in connection with problems allied to the alleged effects of anthropogenically produced climatic changes.

By taking core samples of the upper sedimentary layer in deep sea reservoirs, and up to the upper part of the continental shelf, by using a core length of appioximately 10-12 m, a record can be obtained of the geological and paleontological history over a period of approximately 1,000,000 years. Since the core samples do not require to be of greater length than this and moreover the sedimentary layers are not especially hard, a hydrostatic sampler is well-suited to this purpose. The use of hydrostatic samplers entails driving a sampler tube down into the sedimentary layer under the influence of the hydrostatic pressure, i.e. the water pressure at the depth at which the sample is taken. Furthermore it is possible to make hydrostatic samplers particularly light and simple in design compared with samplers which require an external power supply, via, mechanical or hydraulic motors or with a built-in motor of some kind. There is also a special advantage with this feature of hydrostatic samplers, since the surveys often take place in distant waters and extremely demanding environments, where it is a considerable advantage to have equipment which is easy to transport and operate,

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There are a number of known gravitation samplers which fulfil these conditions to some degree, but if they are to obtain a satisfactory depth of penetration, they have to be relatively heavy as they require a ballast in the order of around 1,000 kg.

From the periodical Marine Geology, volume 54 (1983/1984, pages M33-M41), there is known an active hydrostatic sampler developed by F. W. McCoy and S. Selvin in 1981. Selvin and McCoy's sampler uses a hydrostatic piston engine which via an internal pulley system is used to lift a drop weight which is then dropped and drives the sampler tube down into the sedimentary layer. The cycle is repeated until the hydrostatic energy potential is exhausted. Some of the availale hydrostatic energy, however, helps to lift the drop weighf and moreover the lifting arrangement with pulleys and rope entails a constructional complication.

hydrostatic sampler which represents an improvement ove nd increases the efficiency of Selvin and McCoy's known ampler.

By using the pressure reservoir as a housing for e complete system, including the valve control, all sensi ve components can be safely housed in the pressure reserv rs container.

Together with its contents, this constit es the mass which is used as a pile-driver. At the same ti the piston in the hydrostatic motor is used directl to run the lifting and dropping operations, thus mini Ising the losses during the energy conversion. When the essure reservoir which forms the sampler's head is lifted a downward directed recoil effect is obtained, and this a n causes a double-acting effect which further contribute o the improvement of the present sampler I over the prior t. The hydrostatic sampler according to the present inv ion thus offers a number of advantages in comparis with the known sampler. Compared to Selvin and cp iMcCoy, sampler, the sampler according to the present invention oer ides a greater ratio between drop weight and hammer mass, a SUBSTITUTE SHEEr 4a The object of the present invention is to provide an active hydrostatic sampler which represents an improvement over and increases the efficiency of Selvin and McCoy's known sampler.

According to a first aspect of this invention there is provided a machine for performing work at great depths, including at least one work tool, at least one hydraulic motor which is adapted to be able to be operated by the surrounding water mass, at least one low pressure reservoir, and at least one intake valve arranged so that the hydrostatic pressure in the surrounding water mass leads water through the valve via a conduit means to the motor and via a further conduit means to the low pressure reservoir, the motor converting pressure energy in the fluid flowing therethrough into energy which can be used Sby the work tool, wherein said at least one hydraulic motor includes a hydrostatic axial piston motor in Scommunication with the low pressure reservoir, the axial 120 piston motor including a high pressure cylinder having at least two separate volumes separated by a piston which is connected to a piston rod, and a motor valve means, said S motor valve means being operable to bring the cylinder volumes alternately into communication with the surrounding water mass and a low pressure chamber of the low pressure reservoir such that the high pressure cylinder acts as a water-driven axial motor, imparting reciprocating movement to the piston.

According to a second aspect of this invention there is provided a hydrostatic sampler incorporating the hydrostatic machine described above, especially for core samples of marine sediments, wherein the sampler includes a cylindrical head and a substantially cylindrical sampler section whose longitudinal axis passes approximately through the centre of gravity of the head, and wherein the sampler section includes a sampler tube having at least one sampler tube section, wherein the head includes a fY q1pressure reservoir having at least one reservoir section, 0 the pressure reservoir includes a low pressure chamber and Y 4b 4b a working cylinder with a high pressure chamber provided in or directly connected with the low pressure chamber, the high pressure chamber is connected via an inlet opening with the outside of the pressure reservoir and via a further opening with the low pressure chamber, in the high pressure chamber there is provided a first piston, with direction of movement along the longitudinal axis of the sampler section, and the sampler section with the sampler tube is arranged to perform a stroke movement in response to hydrostatic pressure on the first piston, during which said piston moves from a starting position to a final position in the high pressure chamber and thereafter due to the weight of the head returns to the starting position during a downwards directed movement of the head and the secondary pump cylinder to abut against So the sampler section.

By using the pressure reservoir as a housing for the complete system, including the valve control, all sensitive components can be safely housed in the pressure reservoir's container. Together with its contents, this S constitutes the mass which is used as a pile-driver. At the same time the piston in the hydrostatic motor is used directly to run the lifting and dropping operations, thus minimising the losses during the energy conversion. When the pressure reservoir which forms the sampler's head is lifted, a downward directed recoil effect is obtained, and this again causes a double-acting effect which further contributes to the improvement of the present sampler over the prior art. The hydrostatic sampler according to the present invention thus offers a number of advantages in comparison with the known sampler. Compared to Selvin and McCoy's sampler, the sampler according to the present invention provides a greater ratio between drop weight and i hammer mass, a higher pump pressure, thus avoiding the need for power transfer V I'a

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KW F and a greater lifting acceleration, which gives a substantial recoil effect, since the lifting acceleration is of the same order as the drop acceleration, which provides a doubling of the force of impact per blow. At great depths, moreover, the lifting forces become even more predominant. In addition the sampler according to the present invention is directly activated by the surrounding sea water, while Selvin and McCoy's sampler uses a membrane and hydraulic oil as a moderator. The sampler according to the invention can therefore be expected to give substantially lower internal losses.

The hydrnt-e q 4 f A= hiP;:Acco,1rdinP to thi IqPi P -i4uniu iV characterized by the features and improvements ribed in the claims 1-19, the reference numbers in th claims corresponding to the reference n s in figs. 1-9, whild a sampler according to the ent invention is characterized by the features and vements which are described in the claims 10-43, 'chi erence numbers in these claims corresponding to The invention will now be described in more detail with reference to drawing figures. In particular will an embodiment of the invention in the form of a hydrostatic sampler be taken as an example, since the sampler can be regarded as a special case of the hydrostatic machine according to the invention. In connection with the description of the sampler, reference will be made to figures 10-18 of the drawing.

Fig. 1 shows schematically the general principle of the present invention.

Fig. 2 is an arrangement wherein an axial piston motor is provided in a low pressure chamber. s Fig. 3 is a more refined version of the arrangment in Fig. 2. l Fig. 4 is an arrangement with a separate, closed hydraulic S/ system. I SSUBSTITUTE

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t ~i:r (ca a, :II Fig. 5 illustrates an embodiment of the invention as an impact device or percussion drill.

Fig. 6 illustrates an embodiment of the invention as a sampler for taking core samples of marine sediments on the seabed.

Fig. 7 illustrates an embodiment of the invention for driving an anchor 70 down into sediments on the seabeds.

Fig. 8 illustrates another embodiment of a "hydrostatic anchor" Fig. 9 illustrates schematically an application of the hydrostatic machine of the invention for providing propulidn of a subsea vehicle.

Fig. 10 is a basic view of a sampler according to the present invention.

Fig. lla illustrates a preferred embodiment of a deep water version of the sampler according to the present invention.

Fig. llb illustrates a preferred embodiment of a version of the sampler according to the present invention for shallow water.

Figs. 12a and 12b illustrate a preferred embodiment of the hydrostatic operating mechanism.

Figs. 13a and 13b illustrate another preferred embodiment of the hydrostatic operating mechanism.

Figs. 14a and 14b illustrate details of the embodiment in figs.

13a and 13b.

Fig. 15 illustrates schematically the lowering of the hydrostatic sampler according to the present invention.

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Fig. 17 illustrates the sampler in fig. 16 during operation.

Fig. 18 illustrates schematically the sampler in operation with full penetration of the sampler tube in the sedimentary layer.

Fig. 1 shows schematically the general principle of the present invention and the basic connection of its main components. A hydraulic motor 2 is connected to the surrounding water masses over an intake valve 4 and a fluid filter 5. The hydrostatic pressure of the surrounding water masses leads water through the filter 5 and the valve 4 into the motor 2 which is adapted to converting the pressure energy of the through-flowing fluid into pressure energy which may be used by a work tool 1 connected with the motor 2. The spent working fluid of the motor 2, i.e. the water now at a substantially lower pressure than the surrounding hydrostatic pressure, is conveyed to a low pressure reservoir 3. It is to be understood that the low pressure reservoir 3 is essentially free of gases other than water vapour, such that the pressure in the low pressure reservoir is limited to the water vapour pressure throughout operating period of the motor 2, this operating period being determined by the cycle capacity of the motor 2 and the c&pacity of the low pressure reservoir. In each work cycle of the motor a certain amount of water at the surrounding hydrostatic pressure is depressurized and emptied to the low pressure reservoir. The operating cycles of the motor 2 continue until the low pressure reservoir is full of water.

A particular embodiment of the general principle of the invention is shown in Fig. 2, wherein the hydraulic motor 2a is provided in a low pressure chamber 11. The low pressure chamber 11 is rigidly connected with a high pressure cylinder 12 which forms part of the hydraulic motor 2a which further consists of a piston 15 and a piston rod 16. The high pressure cylinder 12 is divided in two cylinder volumes 120a and 120b on either side of piston 15. During operation the cylinder volumes 120a and

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120b are brought into alternating connection with the surrounding water masses via valves 13a and 13b and with the low pressure chamber 11 via valves 14a, 14b such that the hydraulic motor 2a now acts as a water-driven axial piston motor and a pulsating movement will be imparted to the piston and the piston rod 16.

In the arrangement depicted in Fig. 3 the hydraulic piston notor 2a is connected with a piston pump 20 comprising a second piston 21 at the end of the piston rod 16 and provided in the second cylinder 22 which is rigidly connected with and has the same center axis as the first cylinder 12. Separate cylinder volumes above and below the piston 21 is connected to the surroundings over two non-return valves depicted on the right hand of the cylinder 22 and with a second hydraulic motor ;b1 via two non-return valves depicted on the left side of the cylinder 22. The axial pump may now be used for driving the second hydraulic motor 2b which may be equipped with a work tool 1. The second hydraulic motor 2b may be of either tile reciprocating or the rotary type, for instance a turbine. In the same way as the axial hydraulic piston pump 2a empties to a low pressure reservoir 3 or low pressure chamber 11, the second hydraulic motor 2b empties to an external low pressure reservoir 3b. It will be seen that the medium displaced by the axial pump 20 is the surrounding liquid and that the pump operates as an open system which "consumes" the surrounding liquid. The choke valve 18 and an accumulator 19 are provided between the valves 4 and 13a, 13b, in order to equalize the flow of the surrounding liquid through the filter Fig. 4 shows a further embodiment of the invention with a separate, closed hydraulic system. The piston pump 20 and a hydraulic engine 31, preferably a rotary engine now together with the accumulators 32 and pressure control valves comprise a closed system which is operated by a separate hydraulic medium, for instance a suitable hydraulic oil, while only the hydraulic piston motor 2a still uses the surrounding water as its operating medium. The accumulators, one of which is indicated SUBSTITUTE

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1'- L II P 9 by 32 and the pressure regulating valves, one of which is indicated by 33 respectively are used for equalizing the supply pressure of the axial pump 20. In order to ensure a smooth operation of the primary hydraulic motor 2a, the low pressure chamb r 11 is connected with an accumulator 40 and an additional low pressure reservoir 3 via a pressure regulating valve 41. The additional low pressure reservoir 3 may be used for extending the operating period of the engine in Fig. 4 as the connection between the low pressure chamber 11 and the reservoir 3 may be engaged or disengaged according to need. The valve 41, of course, controls the differential pressure between the chamber 11 and the reservoir 3, being a differential pressure limiting valve.

4 .C d Fig. 5 shows the hydrostatic engine according to the inverti'on embodied as an impact device or percussion drill. The high pressure cylinder 12 is now arranged with its longitudinal axis approximately perpendicular to the seabed and the piston rod 16 is rigidly connected with an impact device with the same longitudinal axis as the piston rod 16. The lower chamber 120b in the high pressure cylinder 12 has a permanently open fluid connection with the low pressure chamber 11 and a constantly closed fluid connection with the external pressure, while only the upper chamber 120a in the high pressure cylinder 12 is adapted to provide an axial motor action. The valve 13a opens at a first stroke, while valve 14a is kept closed and hence the piston 15 is imparted a downwards directed movement and imparts a downwards directed impulse to the impact device 17.

Simultaneously the cylinder 12 with the low pressure chamber 11 is given an upwards directed reaction movement. At the next stroke the valve 14a opens, while valve 13a is kept closed and the low pressure chamber 11 and the high pressure cyl.nder 12 are now imparted a dropping movement that ends with a second downwards directed i-mpulse to the impact device 17, whereafter the first stroke once more is repeated. The cycles repeat until the low pressure reservoir 11, 3 is full or the intake valve 4 is closed. As mentioned the impact device 17 may be a percussion drill, but a person skilled in the art will see that

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2850n '7 it is possible to convert the downwards directed pulsation or storke at least partially to a rotational movement via a per se known mechanical movement converter 170 attached to the drill stem. As shown in Fig. 6, the axial pump 20 may be used for operating a hydraulic rotary motor 50 which imparts a rotational movement to the impact or percussion device 17. The impact device 17 may form the uppermost end of a sampler tube consisting of one or more sampler tube sections which are adapted for taking samples of sediments in the seabed. Hence the embodiment of the invention as rendered in Fig. 6 operates as a bydrostatic corer.

Fig. 7 shows a further embodiment of the hydrostatic machine according to the invention. In this embodiment the machine is used for driving an anchor 70 down into the sediments on the seabed. The impact device 17 forms the crown of an anchor consisting of several arms 71 hinged near the crown 17 in order to offer as little resistance as possible when the anchor is driven into the seabed. The hinged arm 71 forms flukes when the anchor chain 72 is tensioned, as the arms 71 then unfolds. The anchor chain 72 is attached to the top of the low pressure chamber 11 and it is seen that the anchor device and the hydrostatic engine according to the invention forms an integral whole in which the machine's specific weight also makes a possible contribution to the effect of the anchor.

Another version of an anchor combine the hydrostatic machine according to invention is shown in Fig. 8. In this case the machine is equipped with a screw 17 with large threads 171 which make it possible to firmly attach the screw to the seabed by imparting a rotary movement to the screw 17. The threads 171 are driven into the sediments with a combined hammering and screwing movement caused by the hydraulic axial piston pump and a rotary hydraulic motor 75 respectively. The screw may hence be used for mooring or attaching the machine or any vessel attached to the machine via e.g. an anchor chain 72 fastened to the top of the low pressure chamber 11.

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mass and a low pressure chamber of the low pressure reservoir such that the high pressure cylinder acts as a water-driven axial motor, imparting reciprocating movement to the piston.

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ii 1 -V e t~ 1 Finally the machine according to the invention may be used for moving a wheeled or caterpillared vehicle 100 on the sea bed, in which case the vehicle 100 may be thought of as the machine 1 according to the invention. A hydraulic motor 8 is connected either directly with hydraulic motor 2a or the axial pump In this case the hydraulic motor 80 is preferably a rotary engine used for imparting a rotary movement to rolling wheels or the driving wheels of a caterpillar and thus providing the necessary tractive force for the vehicle to move on the seabed.

In this cz.se the hydraulic motor 80 will be equipped with suitable speed regulating means and allow for the steering and the speed of the vehicle to be controlled.

Fig. 10 illustrates schematically the sampler according t( the presert invention. The hydrostatic sampler comprises a pressure reservoir 1 which forms the head of the sampler and which is composed of sections, thus enabling the volume of the pressure reservoir to be regulated according to the number of sections used in the embodiment. Within the pressure reservoir 1 there is provided a high pressure cylinder 13 attached to the walls of the pressure reservoir. The high pressure cylinder has a high pressure chamber which via openings 133 and 134 is connected with a low pressure chamber 14 which is formed by the upper volume of the pressure reservoir 1, and via an inlet valve 11 in connection with the outside of the pressure reservoir. Furthermore the high pressure chamber 130 constitutes the cylinder of a pump device which in reality is the sampler's motor, there being provided in the high pressure chamber 130 a first piston 131. This piston 131 is rigidly connected via the piston rod with a second piston 21 in a secondary pump system 2 which is fitted to an extension of the pressure reservoir 1. The object of the second piston 21 is first of all to cause the transfer of impact, or the lifting movement between the pressure reservoir 1 arid a sampler section 3 which comprises the sampler tube 30, and secondly to provide a secondary pump system 2, in which the pump cylinder 2 can be S emptied into the environment or used to inject water into the it ihe r vr

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of SUSIUE IlE great nyarostatic pressure are admitted into a low pressure reservoir via a hydraulic motor The machine uses a built-in low pressure reservoir as a hydrostatic accumulator, the energy which is released when the surrounding fluid is admitted into the low pressure reservoir being determined by the product of the pressure difference and the internal volume of the low pressure reservoir. In a special version (Fig. 10) the machine is designed as a hydrostatic sampler which is particularly adapted for taking core samples or marine sediments on the seabed.

CI I' -r r 12 conduit 35 in order to provide lubrication of the sampler tube via a three-way valve 22.

In the low pressure chamber 14 of the pressure reservoir 1 there is further provided a pressure relief valve 10 to the environment, while an equalization of pressure is obtained in the non-active cylinder volume in the secondary pump system 2, via opening 203 and three-way valve 22 respectively. The top plate of the pressure reservoir 1 is provided with an eye-bolt for the attachment of lines, while the pressure reservoir's top and bottom plates are attached by means of assembly bolts 7.

The fitting of further sections to the pressure reservoir 1 can then be performed very easily by loosening the top or bottom plate of the pressure reservoir 1 and fitting the required number of extra sections, the length of the assembly bolts used naturally corresponding to the required length of the pressure reservoir 1.

Figures lla and llb illustrate in more detail a preferred embodiment of the hydrostatic sampler according to the invention. Fig. lla illustrates a deep water version of the sampler, wherein the internal volume of the high pressure chamber 130 in the high pressure cylinder is reduced by the insertion of a lining 135, as is more clearly illustrated in fig. 12a. The ratio between the volume of the low pressure chamber 14 and the high pressure chamber 130 is thereby increased, thus eiabling a correspondingly larger number of strokes to be achieved at great depth under a greater hydrostatic pressure, the number of impacts obviously being determined by the ratio between the chamber volumes. Fig. llb illustrates a shallow water version of the hydrostatic sampler and, apart from the lining in the high pressure chamber 130, is exactly the same as the version in fig. lla. On the outside of the pressure reservoir 1 there are provided protective bars 4 and between these and the pressure reservoir 1 or the head there is installed a water filter which is connected with the inlet valve 11. This inlet valve 11 is closed during lowering and not opened until the sampler is in position on the seabed SUBS .ITU..

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and ready for use, via, a line-triggered manoeuvering device 110 for the inlet valve 11. The high pressure cylinder 13 is illustrated in more detail in figures 12a, 12b, 13a and 13b. Around the upper section of the high pressure cylinder 13 there is provided a sleeve-shaped slide valve 15 which can be moved axially around the upper section of the high pressure cylinder. The valve housing 15 is provided with an inlet opening 150 which communicates with a corresponding inlet opening 133 in the high pressure cylinder 13 when the slide valve is located in an upper position on the high pressure cylinder, at the same time as the piston 131 in the high pressure cylinder is located in a starting position. The inlet opening 150 on the slide valve 15 is further connected with the inlet valve 11 via a flexible hose 12. When the sampler is positioned on the bottom, the manoeuvering device 110 is triggered, the inlet valve 11 opened and water under the surrounding pressure streams through the flexible hose 12 and into the high pressure chamber 130, the piston 131 in the high pressure cylinder as shown in, fig. 12a or 13a, being located in the starting position and the slide valve 15 in an upper position. The water which now flows into the high pressure chamber 130 under the hydrostatic pressure drives the piston 131 downwards and a corresponding movement of the connected piston 21 in the attached secondary pump system is obtained, this piston 21 also being in the upper Gtarting position, as is most clearly illustrated in fig. lla. In the starting position the slide valve 15 is kept pressed against the upper part of the high pressure cylinder 13 by a compression spring mechanism 16 which is arranged to work in conjunction with the piston 131, which will be explained in more detail in the following section.

A first embodiment of the compression spring mechanism 16 is illustrated in fig. 12a, where the piston 131 is; located in the starting position and in fig. 12b, where the piston is located in the final position. The compression spring mechanism here comprises a helical spring which is placed in a spring housing 162 and fitted around a spring bolt 161. The spring bolt 161 is p ON -SUBSTITUTE

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i: passed through a fixed circumferential disc 151 on the slide valve 15 and a fixed locating disc 132 arranged on the piston rod at the bottom of the piston 131. The spring bolts are provided parallel to the piston and the spring housing 162 is installed in the high pressure cylinder 13 beside this, as illustrated in fig. 12a or fig. 12b. On the end of the spring bolts are fitted stop nuts 163 and 164. In the starting position of the piston 131, the slide valve is kept pressed into its upper position by the compression spring 160 by means of the capture disc 132 which causes the spring housing to abut against the stop nut 164, thus causing the tension in the compression spring 160 to be completely relaxed and the upper stop nut 163 on the spring bolt 161 to abut against the circumferential disc 151 on the slide valve 15 and to draw this with it into a lower position, thus interrupting the communication between the inlet openings 133 and 150 and stopping the flow of water to the high pressure chamber 130.

Thus when the tension on the compression spring 160 is relaxed, a tension spring 170 which is attached to the high pressure cylinder 13 and the slide valve 15 is pulled into a lower position and the outlet opening in the high pressure chamber 130 is now connected with the low pressure chamber 14 and emntied into it. The pressure in the high pressure :hamber 130 i3 thereby equalized to the pressure in the low pressure chamber 14, which initially, is under atmospheric pressure. Under the weight of the pressure reservoir 1 or the sampler's head and if the pressure in the high pressure chamber 130 is equalized, the piston 131 now returns from the starting position to the final position, while at the same time the capture disc 132 once more abuts against the valve housing 260o and stretches the compression spring 160 which via the circumferential disc 151 again presses the slide valve into the upper position and creates a connection from the inlet valve 111 and through the openings 150 and 133 to the high pressure chamber which is filled once again, whereafter the piston stroke is repeated. The tension spring 170 which is considerably weaker than the compression spring 160 is again stretched during this operation, but naturally cannotcounteract the return movement SUBSTITUTE

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-7>7 2 of the slide valve 15. Thus it can be seen that the slide valve together with the openings 133, 134 and 150 constitute a valve mechanism for the high pressure cylinder 130 which, together with the piston 131 in reality constitute a hydrostatic motor for the operation of the sampler. Figures 13a and 13b illustrate a second embodiment of the spring mechanism for manoeuvering the slide valve 15, fig. 13a illustrating the piston 131 in the starting position and fig. 13b the piston in the final position. Furthermore, figs. 13a and 13b correspond to figures lla and llb respectively and describe the same embodiment as illustrated there. Here too, parallel to piston 131 beside the high pressure cylinder, there is provided a spring bolt 161 which is passed through an opening on the side of the high pressure cylinder, and through the circumferential disc 151 with which it is permanently connected. During a.

piston stroke when the chamber 130 is filled, the capture disc 132 abuts against the stop nut 164 at the end of the rod and compresses the spring 160a against the circumferential disc 151 on the valve housing 15, which under the influence of the spring 160a is pressed against its lower position. At the same time the capture disc 132 also abuts against a stop nut 194 on the end of a camshaft 190, which similarly is arranged parallel to the first piston 131 on the outside of the high pressure cylinder 13 and passed through an opening on the side of this.

On the camshaft 190 there is provided a cam disc 191, the camshaft and cam disc thus constituting a cam mechanism which can engage with cam groove 182 on a ratchet mechanism 18. The blocking mechanism 18 is located in the starting position of the slide valve 15 in blocking abutment against the circumferential disc 151, but the blocking is cancelled when the camshaft 190 is pulled with the capture disc 132, thus cancelling the engagement between the camshaft 191 and the cam groove 182 in the ratchet mechanism. The slide valve thereby moves without hindrance under the influence of the compression spring 160a to the lower position, while a helical spring mechanism 17 which is attached to the upper section of the high pressure cylinder 13 and the camshaft, now that the cam disc is disengaged from the ratchet mechanism, pulls the -SU9STIUT- Stitl c i~

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t 14 i,.o rii ,;4x2 I suBSTITUT S1--EET esampler, the sampler according to the present invention .des a greater ratio between drop weight and hammer mass, a i :r r~nr camshaft 191 upwards, thus engaging the cam disc once again with the cam groove 182 in the ratchet mechanism 18, and the slide valve 15 via the circumferential disc engages in a locking manner with a locking groove 181 on the ratchet mechanism 18. The slide valve is thereby moved by the compression spring 160a and ends in its lower position, securely locked in this position by the ratchet mechanism 18, whereby free passage is created between the high pressure chamber 130 and the low pressure chamber 14 via the opening 134, thus equalizing the hydrostatic pressure, and the piston 131 begins the return stroke back to the starting position under the weight of the pressure reservoir or head 1 and the falling pressure in the high pressure chamber 130. During the return stroke the capture disc 132 pulls the sleeve 195 which is permanently fitted on to the camshaft 190 and also the sleeve 165 on to the spring bolt 161, during which the cam disc 191 is disengaged from the ratchet mechanism 18 and at the same time the compression spring 160b is stretched. The locking of the slide valve in the lower position is thereby cancelled and it is moved under the influence of the compression spring 160b back to its upper position, while the connection between the environment and the high pressure chamber 130 via the openings 150 and 133 is reestablished, thus enabling the cycle to be repeated.

The compression springs 160a and 160b are preferably designed as Belleville springs. As already described, the springs in the helical spring mechanism 17 are a tension spring 171.

The first piston 131, as illustrated schematically in fig. 10 and in more detail in, fig. 12a, is rigidly connected via the piston rod with the second piston 21 in the secondary pump I system 2, as is most clearly illustrated in figures lla and llb. In fig. lla both the pistons 131 and 21 are shown in I their starting positions. When the first piston 131 moves, the second piston 21 in the secondary pump cylinder 20 is moved to act upon the sampler tube which is connected to the lower end of the secondary pump piston 21 via the sampler tube adaptor U-7T1UTF" :j ed V, one sampler tube section, wherein the head includes a I- pressure reservoir having at least one reservoir section, i 4 ok ,the pressure reservoir includes a low pressure chamber and

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b 33. This can slide on the control bolt 24 which is attached in the locking ring 201 on the lower part of the secondary pump cylinder 20, and prevents the sampler tube 30 or the sampler tube adaptor 33 from rotating on the secondary pump piston 21.

On the secondary pump cylinder 20 there is provided a three-way valve 22 which is opened during the lowering of the sampler and causes water to enter in under hydrostatic pressure into an annular space 202 which in the secondary pump piston's 21 starting position is created between the sliding bearing 200 on the secondary pump piston and the sliding bearing 211 on the inside of the wall of the secondary pump cylinder 20 when the sampler is positioned on the seabed, while at the same time it is opened for the working stroke of the piston 132. The secondary pump piston 21 is forced downwards, while at the same time the inlet opening in the three-way valve 22 is closet. 'In its place a connection is obtained between the annular space 202 and an outlet opening in the three-way valve which is connected with a flexible hose 23. Under the influence of the secondary pump piston 21 the water is now forced out of the annular space and into the flexible hose 23 which is connected to an inlet opening in the sampler tube adaptor 33. This inlet opening in the sampler tube adaptor 33 is connected with one or more water injection conduits 35 on the side of the sampler tube. The object of these water injection conduits is to reduce the friction and provide fluid lubrication during the penetration of the sampler tube 30 into the sedimentary layer.

During the drop stroke, i.e. the return movement of the piston 131, the secondary pump cylinder 21 and thus the head 1 abut against the sampler tube adaptor 133, the secindary pump piston 21 returns to the starting position and the water is forced out via the opening 203 in the upper volume of the secondary pump cylinder 20, while the annular space 202 which is again formed during the return movement via the three-way valve 22 is connected with the environment and once again filled with water under hydrostatic pressure, after which the cycle is repeated.

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i iB Ua T1 SVHf:ET I: ~i ii i I The operation of the hydrostatic sampler according to the invention will be described in more detail in connection with figs. 15-18. In reality the procedures used are not substantially different from those used in gravitation samplers. In fig. 15 the sampler 1 is illustrated during lowering from, a research vessel. The head or pressure reservoir 1 is attached to the lowering line and on the sampler section 3 there is provided an attachment point for a support leg 6, which is shown closed around the sampler tube Release lines 60 for the support legs are shown hanging in a slack arc around the sampler. Inside those safety bars illustrated, in fig. llb, the sampler according to the invention will be equipped with completely different instruments, including an inclination sensor for detecting the sampler's true inclination on the seabed, a sonar device or' measuring the distance to the bottom, depths of penetration and also for the transfer of information on inclination. The sonar device, which is not illustrated in more detail, but ihich may be, a known per se modulated pinger, indicates the distance to the bottom, thereby enabling the support legs 6 to be released and brought into position by the release line before the sampler reaches the bottom, the support legs sliding along the sampler tube to abut against the sampler head 31 as illustrated in fig. 16. Any inclination indicated can now be compensated by means of the lines 60, thus allowing the sampler tube to be positioned in a substantially vertical manner. By means of the initial impact the sampler tube 30 is now driven down into the sedimentary layer as illustrated in fig. 17. The driving operation continues in an alternating stroke cycle until the desired depth of penetration is achieved or the hydrostatic energy potential approaches zero. This usually involves approximately 200 strokes, depending, as mentioned above, on the ratio between the volume of the low pressure chamber and the volume of the high pressure chamber. After sampling is completed, the sampler and the sampler tube with the core sample are pulled up to the surface by means of a lifting line, the pressure in the high pressure chamber 130 and S.the low pressure chamber 14 now being the same and identical sviEE

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SLi8 STITUTE SHEET i- Fig. 4 is an arrangement with a separate, closed hydraulic system.

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19 with the surrounding hydrostatic pressure. During lifting the borehole is refilled with water to prevent the creation of a vacuum when the core sample and the sampler tube are pulled out. During lifting the pressure reservoir is decompressed via the pressure relief valve In a typical and preferred embodiment the hydrostatic sampler according to the invention weighs approximately 550 kg without the sampler tube. It is arranged to work at water depths between 200 and 6,000 m and consequently must be designed tc resist the pressure forces which prevail at such depths.

Depending on the water depth the number of strokes can be approximately 200 with an stroke length of approximately 350 mm. The possible penetration, depending on the nature of the sediments, can amount to up to 30 m, which means that the cQre sample's length is 30 m and this again means that special precautions must be taken on the mother vessel when the core sample is taken aboard. The stroke frequency used can vary from, e.g. 0.6 3 Hz, i.e. the actual sampling operation can be performed in the course of a few minutes or less. The stroke frequency can be adjusted via the inlet valve 111, and this is usually necessary as too high an stroke frequency results in severe dynamic loads on the piston rod. It will be obvious to those skilled in the art that there are a number of structural requirements which have to be satisfied in a hydrostatic sampler of this kind, with the purpose of operating at depths as low as 6,000 m. It is, important to dimension conduits and valves in order to avoid flow friction loss and there are naturally special requirements regarding resistance to corrosion, which can be met by the choice of the correct corrosion- and pressure-resistant materials.

The operation of the sampler can be monitored by means of a hydrophone connected to an amplifier aboard the mother vessel in order to record the sound of the impacts.

If the sampler is to be used in particularly hard sediments, the sampler head 31 can be designed as a rotary drill chisel to SUBSTITUTE

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t?4-1 which a rotating motion is provided by, converting a part of the impact energy to rotary motion by means of a suitable device, and in a known per se manner. The rotary movement could possibly also be provided directly by an additional hydrostatic motor.

With regard to the sampler tube itself, it is designed in a known per se manner and composed of sections which may, e.g., be 3 m in length. The individual sampler tube sections are connected by means of a tube section adaptor 36 which also provides fluid connection between the water injection conduits inside the individual sections. In the sampler tube there is further provided a core retaining device 32 which grips the core and is pushed upwards in the tube sections during penetration.

The above description illustrates examples of preferred embodiments of the sampler according to the invention, but it will be obvious to those skilled in the art that further, advantageous variations will be possible within the scope of the invention as disclosed by the appended claims.

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Claims (33)

1. A machine for performing work at great depths, including at least one work tool, at least one hydraulic motor which is adapted to be able to be operated by the surrounding water mass, at least one low pressure reservoir, and at least one intake valve arranged so that the hydrostatic pressure in the surrounding water mass leads water through the valve via a conduit means to the motor and via a further conduit means to the low pressure reservoir, the motor converting pressure energy in the fluid flowing therethrough into energy which can be used by the work tool, wherein said at least one hydraulic motor includes a hydrostatic axial piston motor in communication with the low pressure reservoir, the axial piston motor including a high pressure cylinder having at least two separate volumes separated by a piston which is connected to a piston rod, and a motor valve means, said motor valve omeans being operable to bxz.-ng the cylinder volumes alternately into communication with the surrounding water mass and a low pressure chamber of the low pressure reservoir such that the high pressure cylinder acts as a water-driven axial motor, imparting reciprocating movement 0 to the piston. 25

2. A machine according to Claim 1, including a f luid filter arranged in the surrounding water mass, such that the fluid flow through the intake valve to the motor flows therethrough.

3. A machine according to claim 2, including a choke valve and an accumul.ator for ecrualizing fluid flow through the filter, located between the intake valve and the motor valve means.

4. A machine according to claim 1, wherein the low pressure reservoir is substantially free of gases other than water vapour, the pressure in the low pressure reservoir being substantially limited to water vapour pressure at the relevant temperature throughout the entire work period f rom the time the reservoir is empty of water until it is completely full of water.

5. A machine according to Claim 1, wherein said piston 4KW r'J ;"d i I CI r ;n II~ $~hh piston motor 2a still uses the surrounding water as its operating medium. The accumulators, one of which is indicated SUBSTITUTE SHEET iiB .UT. SHEET....NEON. 22 is rigidly connected to a further piston via said piston rod, and said further cylinder includes non-return valve means thereby to act as an axial pump.

6. A machine according to claim 5, wherein the medium pumped by the axial pump is the surrounding liquid, and the pump operates as an open system which "consumes" surrounding liquid.

7. A machine according to Claim 5, wherein the medium pumped by the axial pump is a commercial hydraulic oil which is provided in a closed system including the axial pump, and a hydraulic motor.

8. A machine according to Claim 7, wherein the closed hydraulic system also includes at least one accumulator and at least one pressure regulating valve for equalizing the supply pressure from the axial pump.

9. A machine according to Claim i, wherein the low Spressure chamber is disengageably connected to an extra low pressure reservoir via a yet further conduit means, S. the low pressure chamber being directly connected to an :20 accumulator, and the differential pressure between the low pressure chamber and the low pressure reservoir being controlled by a differential pressure limiting valve.

1 0. A machine according to Claim i, wherein the high pressure cylinder is arranged with its longitudinal axis '25 approximately perpendicular to the seabed, the piston rod is rigidly connected to an impact device having substantially the same longitudinal axis as the piston Srod, the lower chamber has a constantly open fluid connection with the low pressure chamber and constantly closed connection with the external pressure, while only the upper chamber is arranged so as to provide an axial motor effect, inlet valve means being opened at the first stroke, while outlet valve means are kept closed, thus imparting to the piston a downwards directed movement and causing a first downwards directed impulse to the impact device, the cylinder with the low pressure chamber being simultaneously given an upwards directed reaction movement, and at the next stroke the outlet valve means is opened, while the inlet valve means is kept closed, thus 4 -40 imparting to the low pressure chamber and the high TI -i' I' V 'S Ii ~"S I,7~ I1i iLow pressure reservoir 11, 3 is full or the intake valve 4 is closed. As mentioned the impact device 17 may be a percussion drill, but a person skilled in the art will see that i sUBSTITUTESHEET IN :::~:..~li-.L.SUBSTITUTE SHEETi*, 23 pressure cylinder a dropping movement which ends with a second downwards directed impulse to the impact device, after which the first stroke is repeated, and so on until the differential pressure between the surrounding water and the low pressure chamber is insufficient, or the intaku valve is closed.

11. A machine according to Claim 10, wherein at least one motor drives an electric generator.

12. A machine according to Claim 10, wherein said impact device is in the form of a percussion drill and the outwardly directed pulsations are partially converted to rotational movement by drive conversion means.

13. A machine according to Claims 5 and 10, wherein the impact device is in the form of a percussion drill and the axial pump is used to operate a hydraulic rotary engine which imparts a rotational movement to the impact device.

14. A machine according to Claims 10, 12, and 13, wherein the impact device forms the top of a sampler tube including one or more sampler tube sections arranged to 20 take samples of sediments from the seabed.

A machine according to Claim 10, wherein the impact device forms an anchor having several arms hinged to the anchor so that the anchor offers little resistance when driven into the seabed, but strong resistance when attempts are made to pull it up, since the arms are then jI unfolded.

16. A machine according to Claims 12 or 13, wherein the impact device is in the form of a screw with relatively large threads, thus causing the screw to be attached to the bottom in such a manner that it anchors the machine and any vessel attached to it.

17. A machine for performing work at great depths, including at least one work tool, at least one hydraulic motor which is adapted in order to be able to be operated by the surrounding water mass, at least -ae low pressure reservoir, and at least one intake valve which is arranged so that thi hydrostatic pressure in the surrounding water mass leads water through the valve via a conduit means to the motor and via a further conduit means to the low 40 pressure reservoir, the motor converting pressure energy IIKW 1 fastened to the top of ai aI r eur unain fastened to the top of the low pressure chamber 11. Z,1 SUBSTITUTE SHEET 24 in the fluid flowing therethrough into energy which can be used by the work tool, wherein said at least one hydraulic motor is a rotary motor installed directly in the low pressure reservoir.

18. A machine according to Claim 17, wherein at least one motor drives an electrical generator.

19. A hydrostatic sampler incorporating a hydrostatic machine according to any of the Claims 1-10, especially for core samples of marine sediments, wherein the sampler includes a cylindrical head and a substantially cylindrical sampler section whose longitudinal axis passes approximately through the centre of gravity of the head, and wherein the sampler section includes a sampler tube having at least one sampler tube section, wherein the head includes a pressure reservoir having at least one reservoir section, the pressure reservoir includes a low pressure chamber and a working cylinder with a high e pressure chamber provided in or directly connected with o the low pressure chamber, the high pressure chamber is connected via an inlet opening with the outside of the pressure reservoir and via a further opening with the low pressure chamber, in the high pressure chamber there is provided a first piston, with direction of movement along the longitudinal axis of the sampler section, and the ,25 sampler section with the sampler tube is arranged to perform a stroke movement in response to hydrostatic pressure on the first piston, during which said piston moves from a starting position to a final position in the high pressure chamber and thereafter due to the weight of the head returns to the starting position during a downwards directed movement of the head and the secondary pump cylinder to abut against the sampler section.

A hydrostatic sampler according to Claim 19, wherein there is provided a secondary pump system including a secondary pump cylinder with a second piston, the secondary pump cylinder being rigidly connected with the head and having the same central longitudinal axis as the head and the sampler tube, and the first piston is rigidly connected with the second piston and with the sampler 40 section. v& Tnt~n a X1 .iij 1' bi 1; i i i :i i i ciix i' i i- a seconadry puuJ PrtF a b i j e -to inject water into the 1, emptied into the environment or used to inject ater into the i r SUBSTITUTE SHEET 25

21. A hydrostatic sampler according to Claim 19 or wherein the high pressure cylinder on the outside of its upper section is surrounded by a sleeve-shaped slide valve moveable in an axial direction around this section, arranged to provide fluid communication between the high pressure chamber and the environment respectively via the inlet opening and between the high pressure chamber and the low pressure chamber via said further opening, the further opening being composed of at least one outlet opening on the upper section of the first piston's cylinder in order to provide fluid communication between the high pressure chamber and the low pressure chamber.

22. A hydrostatic sampler according to Claim 21, wherein the inlet opening is in fluid communication with the high pressure chamber via a first flexible hose which is S: attached to an inlet opening on the slide valve, the inlet o opening ,n the slide valve being capable of fluid communication with at least one inlet opening in the upper section of the cylinder. :20

23. A hydrostatic sampler according to Claim 21, wherein there are provided two sets of spring mechanisms around one or more spring bolts which are slidingly arranged parallel to the central longitudinal axis, the first set of spring mechanisms includes springs which extend between a circumferential disc on the slide valve and a stop disk permanently connected to the spring bolts, the second set of spring mechanisms extend between the circumferential disc and a locating disc on the lower end of the first piston, and the capture disc abuts against a stop disk on the lower end of the spring bolts when the first piston Sapproaches its lower end position, thus causing the first set of spring mechanisms to be tensioned, while the locating disc tensions the second set of spring mechanisms when the first piston approaches its upper position, the circumferential disc and the slide valve being affected by a spring load directed towards the same end position when the first piston is located close to an end position.

24. A hydrostatic sampler according to Claim 21, wherein J spring mechanisms are provided around one or more AD camshafts on both sides of a disk which is permanently -I V f l^ K^ K inlet valve 11. This inlet valve 11 is closed during lowering and not opened until the sampler is in position on the seabed StiZET, tP4T SU3STTU ~Ij >1 If:" 26 connected to the high pres'sure chamber, the springs in the spring mechanism extend between the disc and fixed points on the camshafts, the camshafts pass freely through the disc and are axially slidingly arranged parallel to the central longitudinal axis, and cam discs are rigidly connected with the camshafts.

A hydrostatic sampler according to Claim 24, wherein there is provided a ratchet mechanism which is arranged to lock the slide valve axially when it is located in its upper or lower end position, the ratchet mechanism is spring loaded in the direction of the locking position and the cam discs, the ratchet mechanism is located in the locking position when the cam discs are located in a groove in the ratchet mechanism, this position of the cam discs which corresponds to the groove also corresponds to a neutral position of the spring mechanism in relation to the camshafts' axial movement, and the ratchet mechanism :is forced away from the camshaft and out of the locking position when the cam disks are forced downwards or upwards and out of the groove.

26. A hydrostatic sampler according to Claim 25, wherein the camshafts pass through a capture disc which is permanently connected with the lower end of the f irst 0 piston, when the piston approaches its lower end position, the capture disc abuts against a disk, nut or the like which is rigidly connected with the lower end of the camshafts, and when the first piston approaches its upper final position, the capture disk abuts against a disk, sleeve, cross section extension or the like which is axially rigidly connected with the camshafts, so that close to an arbitrary final position the first piston forces the camshafts with the cam disks out of their neutral position and causes an opening of the ratchet mechanism.

27. A hydrostatic sampler according to Claim 19, wherein the volume of the first piston's cylinder is reduced by a lining provided ini the high pressure chamber, the first piston being given a correspondingly reduced dimension. 2

28. A hydrostatic sampler according to Claim 19, wherein 401 between the low pressure chamber and the outside of the k Ii h comprises a helical spring which is placed in a spring housing 162 and fitted around a spring bolt 161. The spring bolt 161 is -C y SUBSTITUTE SHE V T 272 27 head there is provided a one-way pressure relief valve, which opens from the chamber to the outside of the head.

29. A hydrostatic sampler according to Claim 20, wherein the secondary pump cylinder is provided with a three-way valve on at least one end, the three-way valve providing fluid communication between the outside of an annular space which i.s created in th(. secondary pump cylinder on the side of the second piston where the three-way valve is provided, and the three-way valve has an approximately direct connection with the outside when the second piston causes a suction effect in the annular space, while the approximately direct connection is blocked at the same time as a connection is opened to a water injection conduit via a second flexible hose when the annular space is compressed by the second piston, and the water S injection conduit is provided in the sampler section in S: order to provide fluid lubrication of the sampler tube or 0% water injection in the core '.ole when lifting the sampler tube.

30. A hydrostatic sampler according to any of the preceding claims, wherein a valve with a spring-loaded valve arm closes the fluid connection between the high pressure chamber and the environment when the valve arm is located in its lower position when overcoming the spring movement which will tend to open the valve and move the valve arm to its upper position, and a weight is attached by a line to the outer end of the valve arm, the weight thus keeping the valve closed until the weight hits the seabed when the sampler is being lowered, and the hydrostatic sampler will automatically begin to perform 4 the impact movement when the distance between the seabed and the head corresponds approximately to the length of the line between the valve arm and the weight.

31. A hydrostatic sampler acording to any of the Claims 19-30, wherein a high pressure hose connects the valve directly or indirectly with a fluid compressor, thus enabling the supply of fluid from said compressor to replace fluid from the environment under operating i ":so*p ?conditions where the hydrostatic pressure in the head's 0 e~~environment is not sufficient to operate the sampler. V TrV 1. than the compression spring 160 is again stretched during this operation, but naturally cannot counteract the return movement SUBSTITUTE SHEET {I I 28

32. A machine for performing work at great depths substantially as herein described with respect to any one of the embodiments illustrated in the accompanying drawings.

33. A hydrostatic sampler substantially as herein described with respect to any one of the embodiments illustrated in the accompanying drawings. DATED 9 June, 1994 :a 01 o o o 0 oe2 ees ft PHILLIPS ORMONDE FITZPATRICK Attorneys for: SELANTIC INDUSTRIES A/S 7327e :I :tn!