Water discharge device for a submerged launching system

Information

  • Patent Grant
  • 6220196
  • Patent Number
    6,220,196
  • Date Filed
    Tuesday, May 12, 1998
    26 years ago
  • Date Issued
    Tuesday, April 24, 2001
    23 years ago
Abstract
The invention relates to a water discharge device for a system for launching objects, including torpedoes, mines, or missiles, from at least one tube built into a fixed or movable submerged structure (e.g., a submarine). The tube is provided with at least one end door and one slide valve connecting it hydraulically to the water ram by a impulse tank filled with water. The impulse tank is built into the submarine hull, and comprises a closed, sealed space in which the water is driven to the tube, under the influence of a leading pneumatic ram acting on a following hydraulic ram controlled by the water contained in the chamber and previously drawn in from the marine environment by an intake line. The chamber is immovably located outside the hull. The pneumatic ram and the hydraulic ram of the water ram are removable and independent so that they can be placed in the chamber or be dissociated therefrom, without maintenance work being performed on the hull, and with only the fluid or electrical connections and launch tubes, properly passing through the hull. The device also has a compressed-gas reservoir directly connected to the piston of the leading pneumatic ram to drive and displace it, with no intermediate line. The piston is connected to an annular discharge piston forming a concentric crown around the pneumatic ram. The piston is able to move linearly and simultaneously with the annular discharge piston, in the corresponding concentric interior of the hydraulic ram. Furthermore, the link between the leading pneumatic piston and the following hydraulic piston is comprised of a yoke connected at its center to an exiting end perpendicular to the leading piston and connected by its free ends to parallel connecting rods and also connected with the concentric following discharge piston. This structure constitutes an integrated coupling movable with respect to the interiors of the pneumatic ram and the hydraulic ram.
Description




BACKGROUND OF THE INVENTION




The invention relates to a water discharge device designed for a system for launching objects from submerged tubes installed on board a submarine or any other type of launcher or movable or fixed submerged structure.




Known devices of this type are used in the military area to launch objects from torpedo tubes on submarines. These devices, illustrated in

FIGS. 1

,


2


, and


3


, are essentially composed of several tubes (a) for launching torpedoes (b) (a single tube is shown in the figures) with doors (c) at their ends and a slide valve (d). These torpedo tubes are connected to a water discharge device by a impulse tank (e) located outside the pressure hull (f) of the submarine (FIGS.


1


and


3


), or inside the pressure hull when the size of the latter permits (FIG.


2


). Impulse tank (e) forms a closed, sealed space into which the water discharge device discharges.




According to

FIGS. 1 and 2

, the water discharge device, called a water ram, is comprised of a pneumatic ram (g) which is located inside the pressure hull of the submarine and which drives, through a mechanical linkage passing through the pressure hull (f), a piston (h) a of hydraulic ram (i) located outside. A high-pressure compressed-air reservoir provided with a firing valve is located near pneumatic ram (g) and supplies the latter with the power necessary for launching. A line (j) extends the hydraulic ram up to the outer hull of the submarine and channels seawater drawn in from the marine environment when the hydraulic piston moves. Certain water discharge devices are equipped with a depth-pressure-resistant line and are provided with a door. A muffler is installed at the exhaust and the drain of the pneumatic ram.




European Patent Application EP 0151980 describes and claims a water ram variant that consists of replacing the pneumatic valve, supplied with compressed air, by a hydraulic ram supplied by a hydraulic fluid, coming from an air-oil accumulator. Another variant, which to date has not been reduced to practice, replaces the pneumatic ram by a linear motor.




According to

FIG. 3

, the water discharge device is a turbopump comprised of an air turbine (k) located inside the pressure hull of a submarine, driving a pump (m) located outside through a speed reduction unit (


1


). A line (n) extends pump (m) up to the outer hull of the submarine and channels the seawater drawn in from the marine environment when the pump operates. A compressed-air circuit composed of an air reservoir (o) and a firing valve (p) supplies turbine (k) when the device is implemented. A muffler is installed at the turbine exhaust.




The operating principle of these devices is described briefly below:




When a water ram actuated by a pneumatic ram is used (

FIGS. 1 and 2

) for a launch, as soon as the firing valve opens, the hydraulic piston driven by the pneumatic ram supplied with high-pressure compressed air from the reservoir, drives the seawater via the impulse tank to the torpedo tube in question, the slide valve of which is open. When the rear of the torpedo tube is pressurized, the weapon is ejected outside the submarine.




In the case of a device using a turbopump (FIG.


3


), the firing valve supplies the turbine with compressed air, which drives the pump via the speed reduction unit. The pump drives the water taken from the marine environment to the rear of the weapon via the impulse tank and the side openings in the torpedo tube. The hydraulic pressure thus established, pushes the weapon out of the torpedo tube.




However, these devices, widely used on submarines, have a number of drawbacks inherent in their design and operating principle. For example, for launching devices using a water ram type device actuated by a pneumatic ram, these drawbacks are as follows:




1) These water ram devices are installed while the submarine is being built and before the bow is installed. These devices stay installed for the lifetime of the craft. The pneumatic ram plus hydraulic ram assembly takes up a great deal of space on either side of the pressure hull and requires an opening to be made in the hull through which the rod of the pneumatic ram slides. When not in use, keeping the device in the “armed” position exposes the mechanical link between the pneumatic ram and the hydraulic piston to stresses from the marine environment (fouling and encrustation).




2) The integrity of the pressure hull is provided by dynamic seals located on the rod of the pneumatic ram, and the surface condition of this link is essential as it must not deteriorate during its translational movement because the seals ensure the watertightness of the pressure hull. This requires frequent maintenance (periodic emptying of the device while on patrol) to preserve a sufficient surface condition so as not to stress the seals.




3) If the seals fail, there is nothing to prevent the seawater entering the craft if the water intake line is insufficiently strong and not equipped with a hull door.




4) When the weapon is being ejected, the operation of the device causes high-speed displacement of the pneumatic ram and the hydraulic ram which are tightly nested in the internal structures and the pressure hull of the submarine. This movement brings about substantial vibrations, which are a noise source that could render the craft detectable by the enemy. During this same phase, admission of compressed air into the drive of the pneumatic ram causes substantial noise.




5) During a lay-up or while the device is being prepared for a further ejection following a launch, exhausting the compressed air in the drive of the pneumatic ram, which takes place in the cramped interior of a submarine, causes the pressure in this enclosure to rise and the submarine atmosphere to cool off noticeably, especially when several ejections are effected over a relatively short space of time. This bleed causes airborne noise inside the submarine which travels across the sea, thus causing the craft to be even noisier.




For launch devices using a turbopump, the drawbacks are as follows:




1) Installation of a turbopump requires a large opening to be created in the forward bulkhead of the submarine. If the turbopump has to be taken apart for maintenance, appropriate maintenance devices must be used requiring a clear passage inside the craft and clearance in the hull for the outside diameter of the mount holding the turbopump to the forward bulkhead of the submarine.




2) The integrity of the pressure hull is provided by mechanical pump elements resistant to depth pressure but also by dynamic seals located on the pump drive shaft that passes through the pressure hull of the submarine.




3) If the seals fail, there is nothing to prevent seawater from penetrating the craft if the water intake line is insufficiently strong and not equipped with a hull plug.




4) Operation of the turbine, in addition to overpressure and cooling of the atmosphere inside the submarine due to escape of the expanded air, creates serious physiological hazards for the crew when a mass of high-pressure air expands within a very short space of time. This sudden expansion produces a very loud airborne noise that requires a large muffler if its effects are to be attenuated.




SUMMARY OF THE INVENTION




An object of the invention is to remedy the drawbacks of these known devices by modifying the design of the water ram in order better to use the pneumatic energy that ensures operation with a lower noise level and without the drawbacks inherent in expansion of compressed air in a small space. Another object of the invention is to eliminate a translationally or rotationally movable element passing through the pressure hull and potentially compromising the integrity of the pressure hull.




Further objects of the invention are to eliminate periodic cleaning of the pneumatic ram rod, and to offer a water ram whose maintenance does not require long lay-ups of the submarine.




The invention enables these objects to be achieved and for this purpose relates to a water discharge device, or water ram, for a system for launching objects, including torpedoes, mines, or missiles, from at least one tube built into a fixed or movable submerged structure (e.g., a submarine). The tube is provided with at least one end door and one slide valve connecting it hydraulically to the water ram by a impulse tank filled with water. The impulse tank is built into the submarine hull, and comprises a closed, sealed space in which the water is driven to the tube, under the influence of a leading pneumatic ram acting on a following hydraulic ram controlled by the water contained in the chamber and previously drawn in from the marine environment by an intake line. The chamber is immovably located outside the hull. The pneumatic ram and the hydraulic ram of the water ram are removable and independent so that they can be placed in the chamber or be dissociated therefrom, without maintenance work being performed on the hull, and with only the fluid or electrical connections and launch tubes, properly passing through the hull.




According to another characteristic of the invention, the device has a compressed-gas reservoir directly connected to the piston of the leading pneumatic ram to drive and displace it, with no intermediate line. The piston is connected to an annular discharge piston forming a concentric crown around the pneumatic ram. The piston is able to move linearly and simultaneously with the annular discharge piston, in the corresponding concentric interior of the hydraulic ram.




According to another characteristic of the invention, the link between the leading pneumatic piston and the following hydraulic piston is comprised of a yoke connected at its center to an exiting end perpendicular to the leading piston and connected by its free ends to parallel connecting rods and also connected with the concentric following discharge piston. This structure constitutes an integrated coupling movable with respect to the interiors of the pneumatic ram and the hydraulic ram.




Other advantages will emerge from the description hereinbelow, for example:




1) The diameter of the hydraulic piston is increased so that its displacement speed during ejection is less than that of a hydraulic piston of a known system.




2) The pneumatic ram is directly supplied by the compressed-gas reservoir, which eliminates piping and distribution systems creating pressure losses and noise source singularities. Moreover, the velocity of the compressed gas as it expands will be that of the displacement of the hydraulic piston.




3) The pneumatic ram operates on the principle of an air-oil accumulator without the necessity, in a series of several successive ejections, of exhausting off the compressed gas since the device is returned to the “armed” position by the available space of the pneumatic ram being refilled with hydraulic fluid by means of a high-pressure pump. Displacement of the pneumatic piston thus re-compresses the gas reservoir.




4) The assembly comprised of the pneumatic ram and the hydraulic ram, nested into each other, is located outside the pressure hull of the submarine with no links therewith other than those of mechanical attachment, fluid, electrical, and monitoring types for this assembly.




5) The assembly thus created is attached to the outer structure of the submarine by mechanical elastic-type links in order to reduce transmission of vibrations to the submarine hull.




6) Except for the very short phase during which the water ram is in use, while placing the pneumatic piston rod in the extended position, the rod is held in the stowed position due to the available space in the pneumatic ram being filled with hydraulic fluid and hence protected from stresses from the marine environment.




7) The water ram can be uncoupled from the submarine simply by disassembling the mechanical connecting links and the fluid and electrical circuit links with minimum effort, thus allowing easier maintenance in the shop or replacement of a complete assembly in minimum time.




8) The equipment installed in the pressure hull takes up limited space and does not require special maintenance equipment.




Still other characteristics will emerge from the description hereinbelow and should be considered separately or in all their possible technical combinations.











BRIEF DESCRIPTION OF THE DRAWINGS




This description, provided as a nonlimiting example, will give a better understanding of how the invention may be reduced to practice, with reference to the attached drawings wherein:





FIG. 1

represents a conventional launching system embodiment;





FIG. 2

represents another conventional launching system embodiment;





FIG. 3

represents another conventional launching system embodiment;





FIG. 4

is an overall view in a section taken along line A—A in

FIG. 7

;





FIG. 5

is a partial view of

FIG. 4

on an enlarged scale;





FIG. 6

is a detailed view of

FIG. 4

showing a drain float valve with which the hydraulic piston is equipped;





FIG. 7

is a cross-sectional view along line B—B in

FIG. 4

;





FIG. 8

is a view of the device according to the invention in a maintenance phase;





FIG. 9

is a schematic diagram of the device according to the invention in the pre-launch phase;





FIGS. 10



a


and


10




b


are schematic diagrams of the device according to the invention in the launch phase; and





FIG. 11

is a schematic diagram of the device according to the invention in the post-launch phase.











DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS





FIGS. 4

,


5


,


6


, and


7


represent an example of the invention on board a submarine equipped with torpedo tubes. In this configuration, which corresponds to the “resting” mode of the device, torpedo tubes


1


containing the weapon


5


to be launched are shown equipped with their rear doors


2


and front doors


3


that can be open or shut. The slide valve


4


, which can be open or closed, block the water inlet orifices


7


. These orifices provide communication between the interior


8


of the torpedo tube


1


whose slide valve


4


is open, and the interior


10


of a impulse tank


9


. It should be noted that, in the example shown, the impulse tank


9


is connected to pressure hull


11


of the submarine, thus creating a closed, sealed space. However, the same sealing function can be provided by another impulse tank arrangement.




The interior


10


of impulse tank


9


communicates with the interior


12


of a hydraulic ram


13


as a result of its open lower part, as well as through ports


14


disposed on the side wall of hydraulic ram


13


. The hydraulic ram


13


is connected to the impulse tank


9


by a flange


35


attached by elastic links


36


. A seal


37


isolates the interior spaces


10


,


12


in the impulse tank


9


from the outside environment.




A pneumatic ram


26


whose flange


27


receives a compressed-gas reservoir


28


, is located concentrically inside hydraulic ram


13


. Seals


29


isolate the interiors of the ram


26


and the reservoir


28


from the outside environment.




A compressed-gas circuit composed of the circuit lines


51




a,




51




b,


provides the communication between the interior of the reservoir


28


and a submarine compressed-gas production and distribution source. This circuit can be shut off by a valve


52


.




An envelope


25


, inside of which is a heat insulator


54


, surrounds pneumatic ram


26


to resist heat exchanges by conduction and convection between the expanded, cooled gas from the reservoir


28


when ejection takes place into the outside environment. The temperature of the expanded gas must not cool the wall supporting the hydraulic piston


15


of the hydraulic ram


13


, so that icing that will not prevent the latter from returning to its position.




The movement of the pneumatic piston


20


of the ram


26


is transmitted to the concentric hydraulic piston


15


which has a circular shape or any other shape matching that of the hydraulic ram


13


, and is annular relative to a yoke


21


and the connecting rods


17


(at least two in number).




The connecting rods


17


are guided translationally by bearings


18


, integral with the supports


19


attached to the hydraulic ram


13


. Each bearing has associated with it a device


16


that brakes the connecting rods


17


when they reach the end of travel for launching. The hydraulic ram


13


and the envelope


25


of the pneumatic ram


26


, whose walls are lined with a material suitable for frictional conditions in the marine environment, serve as a concentric guide for the piston


15


. The dynamic seal between the concentric interior space


12


and the outside environment is provided by the seals


22


,


23


. The seal


22


on the interior space


12


side, is preferably of the scraper ring seal type.




According to

FIG. 6

, the piston


15


is provided with drain float valves


24


placed between the links with the connecting rods


17


. In the position shown, these valves, in addition to draining the air trapped in the interior interior space


12


, supply the space


12


with water from the outside when the piston


15


returns to the “armed” position after a launch.




The interior


31


of pneumatic ram


26


contains a hydraulic fluid and can be made to communicate with a compensating tank


6


by means of a circuit comprising a flange


30


to which pipe sections


32




a


-


32




d


are connected and through the device combining a valve


33


that can be open or shut and a flow regulator


34


controlling the hydraulic fluid discharged to compensating tank


6


when the piston


20


moves. The movement of the latter is impeded at the end of launch travel by a braking device


55


built into the flange


30


.




A hydraulic fluid circuit composed of pipe sections


29




a


-


29




c


drives the hydraulic fluid contained in compensating tank


6


, by means of a pump


56


, into interior space


31


in order to cause the piston


20


to move from its end-of-launch position to the “armed” position. This movement also has the consequence of compressing the volume of expanded gas in the reservoir


28


. A valve


53


shuts off this circuit when not in the utilization phase and a check valve


38


prevents the circuit from being pressurized upstream of the valve


53


.




Above the hydraulic ram


13


is a support


39


connected by elastic links


40


to a structure


41


integral with the impulse tank


9


. This support takes up the forces developed by the pneumatic ram


26


and for this purpose has a link


50


immobilizing the body of the ram


26


.




A water intake duct


42


fitted with a grid


43


, connects the outer hull


49


to the support


39


. A flexible seal


44


ensures continuity of the profile of the outer hull


49


.




A circuit composed of pipe sections


45




a


-


45




b


and the valve


46


, which can be open or closed, equalizes the pressure between the interior spaces


10


,


12


and the outside environment, or isolates them altogether from the outside environment.




In this embodiment, the water ram is installed in the upper part of the submarine, but any other arrangement fulfilling the same functions, can be contemplated. The electrical monitoring circuits of the device are not shown.




According to

FIG. 8

, removable connectors


47


,


48


, placed between the elements of the lines


32




a


-


32




d,




51




a


-


5




b,


are placed such that, after being disconnected, they allow ram assemblies


13


,


26


to pass through the openings in the upper part of the chamber


9


, in the structure


41


, and in the outer hull


49


.




The water discharge device operates as follows with respect to

FIGS. 9

,


10


and


11


. According to

FIG. 9

corresponding to the pre-launch situation of the device, the torpedo tube


1


containing a weapon


5


to be launched has been prefilled with water and the pressure in the interior space


8


has been equalized with the pressure in the interior space


10


. Then, the doors


3


,


4


are opened and the equalizing valve


46


is closed.




The pneumatic piston


20


connected to the concentric hydraulic piston


15


, is held in position I by the space


31


filled with hydraulic fluid, the latter being unable to flow to compensating tank


6


when the valve


33


is kept closed. The interior


36


of the reservoir


28


is filled with gas at the pressure corresponding to the launch conditions.




According to

FIG. 10



a


corresponding to the launch position, the valve


33


is opened, causing discharge to the compensating tank


6


via pipe sections


32




a


-


32




d


and through the device


34


that regulates the flow of the hydraulic fluid contained in interior space


31


. The displacement of the pneumatic piston


20


to position II is caused by the pressure of the compressed gas contained in the reservoir


28


. The concentric hydraulic piston


15


entrained by the pneumatic piston


20


pushes water from space


12


to space


10


of the impulse tank


9


, and thus supplies the interior


8


of the torpedo tube


1


with water under pressure through the water inlet orifices


7


, causing the weapon


5


to be launched and the space


12


to be supplied while the weapon


5


is traveling to its point of exit from the torpedo tube


1


.




When the hydraulic piston


15


reaches position II, the braking devices


16


and


55


incorporated with the guides


18


and the flange


30


, respectively, begin to act and slow down the movement of the pistons


15


and


20


between positions II and III. The movement is stopped when the piston


20


contacts the flange


30


. While the piston


15


is moving between positions II and III, the piston


15


is gradually uncovering the ports


14


in the hydraulic cylinder


13


to supply the interior


10


of the impulse tank


9


with water from the outside environment to avoid a water hammer when the moving water column abruptly stops.




According to

FIG. 10



b,


another embodiment is shown and can be designed to provide the latter function. For example, the ports


14


are eliminated and passage of water from the outside environment to the interior spaces


10


,


12


when the piston


15


slows down, is provided through the openings in the float valves


24


whose characteristics (i.e., passage cross section, pressure differential causing them to open) are matched to this application (see FIG.


6


).




Finally, according to

FIG. 11

corresponding to the return of the device to the “armed” position, the door


4


of the torpedo tube


1


that has just ejected is closed, as is the firing valve


33


. The equalizing valve


46


is re-opened.




The opening of the valve


53


and the starting of the pump


56


, supply the interior


31


of the pneumatic ram


26


with hydraulic fluid under pressure, taken from the compensating tank


6


and through pipe sections


29




a


-


29




c,




32




a


-


32




c.


The pressure generated by the pump


56


is such that, in view of the power section of pneumatic piston


20


on the hydraulic fluid side below the section of this same piston


20


on the compressed-gas side, the thrust generated by pressurization of space


31


is greater than the thrust due to the partially expanded compressed gas in the reservoir


28


. The movement to position I of the piston


20


and the entraining piston


15


is then accomplished, as is compression of the gas contained in the reservoir


28


.




While the piston


15


is returning to position I, the float valves


24


act as check valves and allow the water taken from the outside environment to pass to the interior


12


of the hydraulic ram


13


.




When the piston


20


is once more in position I, the valve


53


is closed and the device is ready for a new launch once the pressure of the compressed gas in the reservoir


28


has been adjusted to nominal pressure.




The device described above is also applicable to ejection of decoys and all other types of counter-measures, as well as ejection of recoverable underwater propelled bodies or ejection of inert bodies for deballasting operations.




While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention as defined in the following claims.



Claims
  • 1. A water discharge device for launching objects from a submerged structure having a pressure hull, an outer hull with an opening therein, and an impulse tank, the impulse tank being a closed and sealed space, the water discharge device comprising:a hydraulic ram; a pneumatic ram, coupled to the hydraulic ram, the pneumatic ram acting on the hydraulic ram to drive water into the impulse tank; wherein the impulse tank is immovably located in the outer hull and the pneumatic ram and the hydraulic ram are removably mounted so that they can be placed in the impulse tank thereby sealing the impulse tank or be disassociated from the impulse tank, by passing the water discharge device through the opening and sealing the water discharge device in the opening without maintenance work on the hull.
  • 2. The device according to claim 1, wherein the pneumatic ram further comprises a pneumatic piston connected to an annular discharge piston so that a concentric crown is formed around the pneumatic ram, the pneumatic piston being able to move linearly and simultaneously with the annular discharge piston, in a corresponding concentric interior of the hydraulic ram.
  • 3. The device according to claim 2, further comprising:a compressed-gas reservoir being in communication with the pneumatic piston, the compressed-gas reservoir applying pressure to directly drive the pneumatic piston displaceably using no intermediate line.
  • 4. The device according to claim 3, wherein the pneumatic piston and the annular discharge piston are connected by a yoke, the center of the yoke being connected perpendicularly to the pneumatic piston and the ends of the yoke being connected perpendicularly to connecting rods of the annular discharge piston, the yoke thus permitting an integrated coupling of the pneumatic piston and the annular discharge piston movable with respect to the interiors of pneumatic ram and hydraulic ram.
  • 5. The device according to claim 4, further comprising:a flange and seals, the flange and seals allowing the pneumatic ram to directly communicate with the compressed-gas reservoir and isolate the interiors of pneumatic ram and compressed-gas reservoir from outside environmental elements.
  • 6. The device according to claim 5, further comprising:at least one compressed-gas line to provide communication between the interior of the compressed-gas reservoir and a submarine compressed-gas production and distribution source.
  • 7. The device according to claim 6, wherein the annular discharge piston comprises drain float valves placed between the connection of the annular discharge piston and connecting rods, the drain float valves bleeding the air trapped in an interior space of hydraulic ram and supply the interior space with water from outside the interior space when the annular discharge piston returns to a post-launch position.
  • 8. The device according to claim 7, wherein an interior of the pneumatic ram contains a hydraulic fluid, the hydraulic fluid flowing between the interior of the pneumatic ram and a compensating tank through hydraulic fluid lines comprising a flange to which pipe sections are connected, a valve, and a flow regulator, the flow regulator controlling the hydraulic fluid discharged to compensating tank when annular discharge piston is displaced.
  • 9. The device according to claim 8, wherein the hydraulic fluid lines further comprise a pump that drives the hydraulic fluid contained in compensating tank through pipe sections into the interior space of the pneumatic ram, the hydraulic fluid causing the annular discharge piston to move from a post-launch to a pre-launch position.
  • 10. The device according to claim 9, wherein the valve shuts off the hydraulic fluid lines when the hydraulic fluid lines are not in use.
  • 11. The device of claim 10, further comprising a check valve to prevent the hydraulic fluid lines from being pressurized upstream of the valve.
  • 12. The device according to claim 1, further comprising:a support located above the hydraulic ram and connected to a structure integral with the impulse tank by elastic connections.
  • 13. The device according to claim 1, further comprising:a water intake duct as a part of the water discharge device connected to the hull and having a flexible seal to ensure the continuity of the hull's profile, the water intake duct being fitted with a grid.
  • 14. The device according to claim 1, further comprising:at least one water line composed of pipe sections and valve, which can be open or closed, the at least one water line equalizing the pressure between the interior spaces of hydraulic ram and the impulse tank respectively, and an outer environment.
  • 15. The device according to claim 1, wherein the water discharge device is installed in an upper part of the submerged structure, the water discharge device further comprising removable connectors being placed between water and hydraulic lines so that, after the lines are disconnected, the water discharge device can pass through the opening in the outer hull at the upper part of the submerged structure.
  • 16. The device according to claim 1, wherein the water discharge device requires only fluid connections, electrical connections, and launch tubes, passing through the hull.
  • 17. A water discharge device for launching objects from a submerged structure having a hull and a impulse tank, the impulse tank being a closed and sealed space, comprising:a hydraulic ram; a pneumatic ram, coupled to the hydraulic ram, the pneumatic ram acting on the hydraulic ram to drive water into the impulse tank; a pneumatic piston connected to an annular discharge piston so that a concentric crown is formed around the pneumatic ram, the pneumatic piston being able to move linearly, simultaneously with the annular discharge piston, in a corresponding concentric interior of the hydraulic ram; the pneumatic piston and the annular discharge piston are connected by a yoke, the center of the yoke being connected perpendicularly to the pneumatic piston and the ends of the yoke being connected perpendicularly to connecting rods of the annular discharge piston, the yoke thus permitting an integrated coupling of the pneumatic piston and the annular discharge piston is movable with respect to the interiors of pneumatic ram and hydraulic ram; wherein the chamber is immovably located outside hull while the pneumatic ram and the hydraulic ram are removable and independent so that they can be placed in the chamber or be disassociated from the chamber, without maintenance work on the hull, and wherein the water discharge device is installed in an upper part of the submerged structure, the water discharge device further comprising removable connectors being placed between water and hydraulic lines so that, after the lines are disconnected, the assembly is allowed to pass through openings in the upper part of the submerged structure.
  • 18. The device according to claim 17, further comprising:a compressed-gas reservoir being in communication with the pneumatic piston, the compressed-gas reservoir applying pressure to directly drive the pneumatic piston displaceably using no intermediate line.
  • 19. The device according to claim 18, further comprising:a flange and seals, the flange and seals allowing the pneumatic ram to directly communicate with the compressed-gas reservoir and isolate the interiors of pneumatic ram and compressed-gas reservoir from outside environmental elements.
  • 20. The device according to claim 19, further comprising:at least one compressed-gas line to provide communication between the interior of the compressed-gas reservoir and a submarine compressed-gas production and distribution source.
Priority Claims (1)
Number Date Country Kind
97 05960 May 1997 FR
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