NL8500162A - DEVICE FOR GENERATING ACOUSTIC WAVES IN WATER. - Google Patents

Description

853005 Ke / ki

Short designation: Device for generating acoustic waves in the water.

The Applicant mentions as inventor Jean-Paul DESSAPT.

The invention relates to a device for generating acoustic waves in the water by the sudden ejection of a liquid mass from a tubular body that is open at one of its ends to the environment, this liquid mass being propelled by the displacement of a main piston connected to an auxiliary piston to form a first movable system, the device comprising an operating system for the first movable system, formed by a second movable system consisting of a secondary piston and an annular piston intended to to slide into the body and be joined by a hollow rod into which the auxiliary piston can slide, the annular piston having a central opening forming a seat for the main piston and means for first and second pressures, higher then the first, bringing fluids, which means interact with a valve that is lifted dt by the abutment 15 of the main piston against that seat, the lifting of the valve bringing the space between the main piston and the annular piston at the same pressure as the surrounding water.

More particularly, the invention relates to an apparatus for emitting acoustic waves by suddenly ejecting a mass of liquid into the water.

Such a device can be used, for example, for conducting seismic survey operations at sea, generating vibrations in the water behind a ship towing a receiving device constituted by a large number of receivers, such as hydrophones distributed along a closed shell, commonly referred to as a seismic whistle, which captures, captures and treats the echoes on the various reflective layers of the sea bed's subsurface to provide a representation of the subsurface.

An apparatus is known for generating acoustic pulses in the water by ejecting a fluid mass which is collected in a chamber within a hollow body, which chamber is open at one end to the environment and bounded at the other end by a first movable piston. The ejection is accomplished by a sudden displacement of a first movable system formed by the first piston and a second piston with which it is joined by a rod, which 8500162-f-eerste first movable system cooperates with the second movable system that can slide within the body and consists of a tubular rod within which the second piston of the first movable system can slide. The operating cycle consists of the separate or simultaneous displacement of the two movable systems under the action of drive means constituted by a hydraulic system and a pneumatic system, cooperating with a control element actuated by contact between the two movable systems, and operating means outside the device that coordinate the movements of the two movable systems and their return, after the shot, to a cocked position.

The operating means comprise three coaxial cylinders insulated from each other, within which respectively three pistons move, which are fixedly connected by the same rod.

15 The whole of the three pistons is movable by the action of a hydraulic system on the piston in the middle cylinder. The displacement of the corresponding pistons in the other two cylinders, one of which contains a liquid and the other is connected to a pneumatic system, makes it possible to move the two movable systems and to start the movement of the main piston. The operation of the device necessitates the use of an electrically operated four-way valve and an external actuator capable of operating the electrically operated valve at two separate times in the cycle, so that the whole of the three pistons alternates in one direction is moved. Such a device is described in French Patent 2,481,382.

The device according to the invention makes it possible to omit the use of an operating member for synchronizing the different stages of the operation and to automatically make the operations of retensioning after a shot.

The device according to the invention comprises a tubular body open at one of its ends to the environment, this fluid mass being propelled by the displacement of a main piston connected to an auxiliary piston to form a first movable assembly 35, which device is provided with a control system for the first movable system formed by a second movable system consisting of a secondary piston and an annular piston intended to slide into the body and joined by a hollow rod into which the auxiliary piston can slide, wherein the annular piston for 8500162

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shows a central opening which forms a seat for the main piston and means for applying fluids at a first pressure and at a second pressure higher than the first, which means cooperate with a valve lifted by the abutment of the main piston against that seat, with the valve lifting up the space between the main piston J

and pressurizing the annular piston to the same pressure as the surrounding water, characterized in that the device comprises a distribution valve and pipes I

to apply a fluid at a high pressure or low pressure against a face of the secondary piston, depending on the position of a movable part movable within the valve under the action of two opposite pressures, one of which is constant, while the the other is equal to the varying pressure prevailing in the space between the main piston and the annular piston.

The fluid pressurizing device comprises, for example, a generator for compressed air at a first pressure, and a source of hydraulic fluid at a second pressure. According to the invention, the preferred embodiment is then characterized in that the compressed air generator is in constant communication with the part of the body situated between the secondary piston and the annular piston, and with the interior of the hollow rod through which the pistons are connected, regardless of the position thereof, and that the alternating pressure prevailing in that space in the rest position of the valve is equal to the pressure generated by the compressed air generator.

The application of the valve with which, at the time of contact between the two movable systems, it is possible to change the pressures acting on the movable part of the distribution valve and thus change the forces exerted on the secondary piston, and the selection of the cross sections of the various elements subjected to the pressures results in the cycle of retensioning being made fully automatic, with the retensioning phase commencing immediately after firing the device .

The invention will be elucidated hereinafter with reference to the accompanying drawing of a preferred embodiment, wherein further measures to be used with advantage will emerge.

Fig. 1 is a schematic sectional view of the device in the cocked position, which is also the rest position; Fig. 2 schematically shows the distribution valve (a slide distributor) for operating a hydraulic 8500162-4- intermittently on the second piston

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fluid; FIG. 3 shows a more detailed cross-section of the portion of the movable element that the control means; FIG. 4 is a schematic sectional view of the device at the end of the firing phase in which the first movable system has reached the end of its forward stroke and in which the second movable system is joining; FIG. 5 is a schematic sectional view of the device at a later time when the second movable system has reached the first at the end of the stroke; FIG. 6 is a schematic sectional view of the device during the return phase of two movable systems to their re-tensioned position.

The device comprises (in particular fig. 1 to 3) an elongated tubular body 1, provided with two coaxial chambers 2, 3 with different cross-sections, which connect to each other via an extension 5. The chamber 2 with the smallest cross-section is open on the side remote from the widening 4 and communicating with the surroundings through a narrowed end portion 5 of the body provided with openings 6. It further comprises a first movable assembly formed by a main piston 7 and an auxiliary piston 8 attached to both ends of a first rod 9, and a second movable assembly formed by a secondary piston 10 formed by a second rod 9 is connected to an annular piston 12. The cross-section of the main piston 7 and that of the annular piston 12 are equal to the cross-section of the chamber 2. Sealing rings 13, -14 are arranged on its periphery so that they can be sealed to slide. The cross section of the secondary piston 10 is adapted to the cross section of the chamber 3 of the body. A sealing ring 15 is arranged on its periphery to allow it to slide sealingly into the chamber 3. The main piston 7 connects to the rod 9 by a truncated conical part 16. A bore 17 with a cross section of the auxiliary piston 8, adapted section is provided in the axis of the movable element and of the second rod 11. It is provided at the entrance with a chamfered portion 18 of a shape adapted to the frusto-conical part 16 of the main piston 7. A ring 18a is attached to the annular piston 12 'near the chamfered portion to better isolate the space 60 of the body between the main piston 7 and the annular piston 12 when they collide with one another. from the rod 11; The plane S2 of the main piston which is under the action of the compressed air 40, when in contact with the annular piston 12 8500162 Λ * -5- and the sealing ring 18a, is smaller than the opposite plane SI of the auxiliary piston 8. On the A sealing ring 19 is provided perimeter of the auxiliary piston 8 to ensure that it slips sealingly. The length of the rods 9 is such that, when the frusto-conical portion 16 collides with the chamfer 18, the auxiliary piston lies substantially on the bottom of the central bore 17.

The secondary piston 10 is provided with a tubular extension 20, on the side remote from the annular piston 12. This body 1 is closed at the end remote from the narrowed part 5 with a cover 21. A sealing ring 61 is arranged on the periphery of the cover. This cover is provided with a central bore with a cross-section adapted to that of the tubular extension 20, at least along a part of its length, this central bore being provided with a circumferential groove for a sealing ring 22.

An opening 23 is provided in the annular piston 12 to permanently connect the second chamber 3 to the central bore 17 of the second rod 11. Two channels 24, 25 are arranged in the annular piston 12 from the plane 12a thereof. opposite the secondary piston 10 (Fig. 3). The channel 24 runs through it, the other 20 channel 25 communicates with an internal cavity 26 which opens into the space 60 on the other side 12b of the annular piston, through an opening 27. A control means can slide into the recess 26 formed by a needle valve 28 configured to isolate the channel 25 from the opening 27 in the rest position. The needle extends through the opening 27 and 25 continues to within the plane 12b so that when the annular piston 12 is against the the main piston, the needle is pushed away and the valve 28 is lifted, creating the connection between the channel 25 and the space 60 between the two pistons 7 and 12.

The two channels 24 and 25 are connected by means of two tubes 29, 30 to two channels 31 and 30 respectively. 32 (FIG. 1) extending through the secondary piston 10 and opening into the interior of the tubular extension 20 thereof. Three more channels 33, 34, 35 also pass through the secondary piston 10. On the one hand, they open into the tubular extension 20, and two of them, 33 and 34, are connected to the two channels of an electrically operated two-way valve 36. On the other, one of the channels, 33, opens out in the annular space between the second hollow rod 11 and the outer wall of the body, and the two other channels 34,35 open into the interior of this second rod in a chamber 59 between the secondary piston 10 and the auxiliary piston 8. The channel 35 is very fine, 8500162 -6- at least over part of its length.

An opening 37 is provided in the side wall of the body 1 at the level of the second chamber 3. A tube 38 connected to a compressed air generator (not shown) is connected to this opening 37, so that a high pressure (for example of the order of 14MPa) is continuously applied in the part of the chamber 3 between the secondary piston 10 and the annular piston 12.

The annular cover at the end of the body 1 is provided with a part 39 (shown in detail in Fig. 2), in which a control system is arranged, the main part of which is a slide distributor 40. This distributor is provided ( see fig. 2) of a barge consisting of three coaxial pistons 41, 42, 43, which are united by the same rod 44 and are movable in a cavity 45 with three mutually connecting chambers 46a, 46b, 46c. A bore 47 is provided through the wall 15 of the lid 21, connecting one of the side chambers 46a to the exterior. A tube 48 is attached at one end to the opening of the channel 31, at the bottom of the tubular recess 20, and at the other end to the outlet of the bore 47. The side chamber 46c at the end 20 facing away from the cavity 45 is extended by a tubular recess 49, which serves to guide the rod 44 at one of its ends. In the two facing chambers 46a, 46c of the cavity, two bores 50a, 50b open to which two pipes 51a, 51b (Fig. 1) are connected which are connected to a hydraulic system of a known and not shown type, which is intended to supply oil to it at high, resp. at low pressure (e.g. 24 MPa and 100 kPa).

A connecting channel 52 is established between the intermediate chamber or middle chamber 46c and the end of the chamber 3 of the body, on the side of the secondary piston 10 facing away from the annular piston 12 (chamber 62, see FIG. 4).

The intermediate piston 42 of the slider has two frusto-conical end portions facing away from each other. Two stops 53, 54 are provided at both ends of the middle chamber 46b. Its shape is adapted to that of the frusto-conical end portions 35 of the piston 42, so that when they come to lie successively against the stop 53 (first position of the slide) and against the stop 54 (second position of the slide) chamber 46b is isolated from chamber 46a or from chamber 46c. The piston 41 slides into the chamber 46a, isolating the bores 47 and 50a from each other, regardless of the position of the slide. The piston 43 slides into the chamber 46c. A channel 55 communicates the bore 50b with the chamber 46c between the piston 43 and the bore 49 which is an extension thereof. The thickness of the piston 43 and the location where the channel 55 opens are chosen such that, in the second position of the slide in which the intermediate piston 42 comes to rest against the stop 54, the piston 43 would block the access of the channel 55 .

Another channel 56 communicates the bore 50a with the tubular recess 49 regardless of the position of the slide in its cavity.

A known type calibrator 57 is provided in channel 56 to inhibit the flow of the oil. A non-return valve 63 is arranged in a circulation on the calibration means 57.

The electrically operated 36 is controlled from a surface! installation using a conductive cable 58.

The device operates in the following manner: The rest position of the device, corresponding to the tensioned state, is that shown in Fig. 1. The second movable assembly is in the retracted position for which the secondary piston 10 is substantially in contact with the lid 21 of the body. The first movable system is also in the retracted position. In this position, the main piston 7 abuts the annular piston 12 and the needle valve 28 is lifted. The connection between the channels 24 and 25 is established by means of the opening 27 and of the space 60 in the chamber 2, and therefore the hydrostatic pressure by means of the channels 24, 25 and of the tubes 29, 30 and 48 are applied to the piston 41 in the chamber 46a of the distributor 40.

The hydraulic pressure which is applied in opposite direction to the rod 44 in the recess 49 at the other end of the cavity is such that the slide is held in its first position (that shown in Figures 1 and 2) and in which the line 52 in connection 50 is with the oil at low pressure in the tube 51b.

The secondary piston 10 is on the side of the lid 21 (chamber 62) under the influence of a low oil pressure and on the other side of the compressed air at a high pressure and is thus kept in the retracted position. Because the needle valve is raised, the main piston is under the influence of the hydrostatic pressure on both sides, except on the frusto-conical section opposite the central bore 17 where it is under the influence of the compressed air. The auxiliary piston is under the influence of the hydrostatic pressure through the channel 35 and the compressed air on the other side. The total force applied to a 40 first movable system and resulting from the forces exerted by the compressed air on the uneven surfaces S1 and S2 results in the main piston 7 against the ring 18 is kept pressed.

Then the opening of the electrically operated firing strike 36 is controlled, whereby the channels 33 and 34 are connected to each other.

As a result, the compressed air ends up on the plane of the auxiliary piston opposite the cover 21 (chamber 3).

The new resultant of the forces applied to the first movable system causes it to move away from the second. 10 The main piston 7 is released from its seat 18 and the compressed air can reach the entire face opposite the annular piston 12. The first movable system is then suddenly driven towards the end portion 5 of the body against which it strikes (fig. 4 and thereby expels the air volume contained in the first chamber 2 through the openings 6. Expulsion of the water at great speed produces strong acoustic waves in the environment.

-. As soon as the first movable assembly has started to move away from the second, the needle valve 28 closes again and the lines 24 and 25 isolate from each other. The compressed air then arrives against the piston 41 of the slide through the channels 34 and 31, of the tube 48 and of the opening 47. The ratio between the respective surfaces of the piston 41 and the rod 44 on the side of the recess 49, as well as the ratio of the pressures of the compressed air and of the oil applied to the slide in opposite directions, are such that it moves to its second position (fig. 4) where the intermediate piston 41 rests on the seat 54, whereby the channel 52 is brought into connection with the bore 50a, where there is a strong hydraulic pressure.

Since this high pressure exerted on the plane of the secondary piston 10 opposite the lid 21 (chamber 62) is greater than the pressure of the compressed air exerted on the opposite surface, the second movable system is in turn driven towards the end 5. of the body where it rejoins the first (fig. 5).

During the entire displacement phase of the two movable adjustment 35 to the end 5, the narrowing of the channel 35 makes it possible to keep the chamber 59 at overpressure and to prevent the water from flowing in from the outside.

While the two movable assemblies are back together and the main piston 7 abuts the ring 18a, lifting the needle valve 28 causes the space 60 between the piston 7 and the annular piston 12 is brought to the hydrostatic pressure, and also the channels 24, 31 and the pipes 29, 48. The resultant of the forces resulting from the application of the hydrostatic pressure on the piston of the slide and of the high pressure of the hydraulic circuit on the rod in the recess 49 remote from it results in the slide being returned to its first position (fig. 6). the calibration means 57 makes it possible to delay its displacement and thus prevent too sudden decompression of the space 62 between the piston 10 and the cover 21.

The result of the return slider to its first position is that the space 62 reconnects with the low pressure hydraulic chain. Since the secondary piston 10, on the other hand, is exposed to the high pressure of the compressed air, the resultant of the forces exerted results in the second movable system being returned to the retracted position (Fig. 6). The resulting force exerted on the movable assembly when the main piston 7 is in contact with the annular piston 12, which, as has been shown above, tends to push the main piston 10 against it, follows the first movable assembly the second in its retracting motion to the tense position shown in FIG. The device is then ready for another shot.

It can be seen that the cycle of tensioning the device after the shot, using the electrically operated valve 36, is fully automatic.

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Claims (7)

1. Device for generating acoustic waves in the water by the sudden ejection of a mass of liquid from a tubular body (1) which is open at one of its ends to the environment, this liquid mass being propelled by the displacement of a main piston (7) connected to an auxiliary piston (8) to form a first movable system, the device comprising an operating system for the first movable system formed by a second movable system consisting of a secondary piston (10) and a annular piston (12) intended to slide into the body and joined by a hollow rod (11) into which the auxiliary piston can slide, the annular piston having a central opening (17) which forms a seat for the main piston and means for applying fluids at a first pressure and at a second pressure, higher than the first, which means cooperate with a valve (28) lifted by the abutment of the main piston (7) against that seat, the lifting of the valve bringing the space between the main piston and the annular piston at the same pressure as the surrounding water, characterized in that the device comprises a distribution valve (40) and conduits for fluidizing a surface of the secondary piston at high pressure or low pressure, depending on the position of a movable portion movable within the valve under the action of two opposite pressures, one of which constant while the other is equal to the varying pressure prevailing in the space between the main piston and the annular piston. 2. Device according to claim 1, wherein the means for pressurizing the fluids comprises a generator for compressed air at a first pressure and a source of hydraulic fluid at a second pressure, characterized in that the compressed air generator is continuously connected to the between the secondary piston (10) and annular piston (12), part (3) of the body, and with the interior of the hollow rod through which the pistons are connected, regardless of their position, and that the the varying pressure prevailing in this space in the rest position of the valve (28) is equal to the pressure generated by the compressed air generator. Device according to claim 2, characterized in that the movable part of the distribution valve 40 comprises a central piston (42), said valve having three coaxial chambers, the intermediate chamber (46b) of which communicates with one of the two outermost chambers (46a, 8500162 -11- 46b) depending on the position of the central piston movable in the intermediate chamber, and wherein the two outer chambers are respectively connected to the low pressure circuit and the high pressure circuit of the source of hydraulic fluid, the opposite ends of the movable portion having unequal cross sections, the end having the largest cross section being exposed to the alternating pressure and the other being exposed to the hydraulic high pressure, and the ratio of the sections of the two ends facing away from each other are chosen such that, when the alternating pressure is the pressure of the compressed air, the movable part moves to a position in which the intermediate chamber (46b) communicates with the high pressure circuit of the source of hydraulic fluid. Device according to claim 3, characterized in that the central piston (42) is connected on the one hand by a rod (44) to a piston (41) which can slide in one of the outer chambers (46a) and is exposed to the alternating pressure, on the other hand with a piston (43) that can slide in the other outer chamber (46c), the latter being extended by a rod (44) that can slide in a tubular recess (49) which communicates with the high pressure circuit of the source of hydraulic fluid. Device according to claim 4, characterized in that the tubular recess (49) communicates with the high pressure circuit through a channel (56) which includes a means (57) for controlling the flow rate with parallel position , a circuit element which is provided with a non-return valve (63). The device according to claim 4, characterized in that said space (60) is connected to one end of the cavity of the distributor (40) by channels (24, 31) passing through the annular piston and the secondary piston and the tubes (29, 48) run. Device according to claim 1, characterized in that the volume (59) of the hollow rod (11) between the auxiliary piston (8) and the secondary piston (10) is in constant communication with the environment of the body through a narrow channel (35) and intermittently, by means of a valve (36) with the portion (3) of the body where the first fluid pressure is constantly prevailing. 8500162