FR3107761A1 - PROCESS AND INSTALLATION FOR EXTRACTING PROPERGOL FROM A PROPELLER - Google Patents

Abstract

The invention relates to a method of extracting propellant (18) from a charged propellant body (12), said charged propellant body (12) comprising an elongated structure (14) with a main axis A which is an element of revolution. around said main axis (A), and within which said structure, the propellant (18) is located, the extraction process consisting in using at least one nozzle (24) producing a jet (28) of liquid which erodes the propellant (18), characterized in that the jet (28) of liquid is a flat jet and in that the nozzle (24) travels a helical path coaxial with the main axis A during the extraction of the propellant (18). Figure for the abstract: Figure 2

Description

METHOD AND PLANT FOR EXTRACTION OF PROPELLANT FROM A PROPELLANT

The invention proposes a method and an installation intended for the dismantling of a propellant, in order to extract the propellant from the loaded propellant body.

PRIOR ART

In the context of propellant reprocessing, whether military or space propellants, there is recycling of the various components of a propellant, as an alternative to their combustion.

For this, in particular, it is necessary to separate the propellant from the structure of the propellant.

The propellant thus extracted from the structure of the propellant is then reprocessed, to extract the components of the propellant, in particular the ammonium perchlorate.

According to a known embodiment, the extraction of the propellant is carried out by cutting the propellant using pressurized liquid jets.

The trajectory of these round jets results in some of the propellant remaining attached to the structure in the form of propellant teeth.

Also, the power of the jets is sometimes too great and when the intersection of jets is located close to the wall, these jets can impact the structure.

According to one embodiment, the material of the structure is based on stainless steel, which makes it resistant to the impact of jets.

On the other hand, when the structure is made of composite material, this material can disintegrate under the effect of the jet of liquid.

The result is that the mechanical integrity of the structure is called into question, it must then be repaired or scrapped. Also, the portion of the structure that is disaggregated mixes with the extracted propellant.

The propellant thus polluted cannot then be reprocessed, it must therefore be eliminated by combustion, with the pieces of structure, thus producing pollution.

The object of the invention is to propose a method and an installation for extracting propellant which make it possible to separate all of the propellant from the structure of the propellant body, without harming the integrity of the structure.

The invention relates to a method of extracting propellant from a loaded propellant body, said loaded propellant body comprising an elongated structure of main axis A which is an element of revolution around said main axis A, and inside which said structure the propellant is located, the method of extraction comprising using at least one nozzle producing a jet of liquid which erodes the propellant, characterized in that the jet of liquid is a flat jet and in that the nozzle travels a helical trajectory coaxial with the main axis A during the extraction of the propellant.

The use of a flat jet makes it possible to distribute the power of the pressurized liquid, which limits the risks of damaging the structure of the thruster body. Also, the fact that the jet is flared makes it possible to reach substantially the entire internal surface of the structure, in order to remove all the propellant.

Preferably, the method is implemented in several phases each consisting in eroding the propellant by the flat jet, over a predefined thickness.

Preferably, an adjustment of the position of the nozzle is carried out between two successive phases, to bring the nozzle closer to the propellant according to a predefined pitch.

Preferably, the trajectory traveled by the nozzle has a pitch substantially equal to an axial extent along which propellant is eroded by the flat jet.

The invention also relates to an installation for implementing a process for extracting propellant from a loaded propellant body according to any one of the preceding claims, which comprises a support pole which is supplied with pressurized liquid and which is movable in translation and rotation along its main axis which coincides with a main axis A of the loaded propellant body, at least one nozzle for projecting a jet of liquid which is carried by the support pole, supply means of the said at least one pressurized liquid nozzle via the support pole, characterized in that the said at least one nozzle is designed to project the liquid in a flat jet.

Preferably, said flat jet is delimited by two straight lines which intersect at the level of the nozzle and which delimit an opening angle of the predefined flat jet.

Preferably, the value of said opening angle of the flat jet is degrees.

Preferably, said at least one nozzle is carried by a support arm making it possible to adjust the position and orientation of the nozzle relative to the support pole, and which provides fluid communication between the nozzle and the support pole.

Preferably, the installation comprises a plurality of interchangeable support arms which are able to be swapped between two phases of the process, to modify the position of said nozzle with respect to the support pole.

Preferably, each support arm is able to pivot relative to the support pole around an axis orthogonal to the main axis A during a phase of the method.

is a schematic representation of a propellant extraction installation according to the invention

is a schematic representation showing a rolling phase for the extraction of the propellant.

is a schematic representation of a support pole that carries several liquid projection nozzles.

is a schematic representation of a support pole showing the possible movements of a support arm.

DETAILED DESCRIPTION OF THE INVENTION

There is shown in Figure 1 an installation 10 for the extraction of the propellant contained in a loaded propellant body 12.

The loaded thruster body 12 comprises a structure 14 of main tubular shape of revolution and having a main axis A.

This structure is open at one of its axial ends 16, the other axial end can be open or closed.

Propellant 18 is present inside structure 14 and is attached to its internal face.

The installation 10 operates by the use of one or more jets 28 of pressurized liquid, carrying out an abrasion of the propellant 18.

Preferably, the liquid under pressure is water. Thus, in the following description, reference will be made to water to form the jets. It will be understood that other liquids can be envisaged and that the use of such another liquid will be deduced from the description by analogy.

The installation 10 comprises a support pole 22 which extends coaxially with the main axis A of the structure 14 and which is rotatable around this main axis A and in translation along the main axis A.

The support pole 22 carries at least one nozzle 24 for spraying water under pressure in the direction of the propellant 18 in the form of a jet 28.

According to the embodiment shown in Figure 1, the support pole 22 carries two spray nozzles 24 which are distributed over an axial end 22A of the support pole 22.

It will be understood that the installation 10 is not limited to these embodiments comprising two projection nozzles and that the installation 10 can comprise a single projection nozzle 24 or several nozzles 24 strategically distributed on the support pole. 22.

In the following description, reference will be made to a single spray nozzle 24 . It will be understood that the description for an embodiment comprising several spray nozzles 24 can be deduced by similarity.

The installation 10 also comprises a support arm 26 for the nozzle 24, which connects the nozzle 24 to the support pole 22.

The support arm 26 makes it possible to achieve a precise positioning of the nozzle 24 with respect to the structure 14 and to the propellant 18 to be extracted, that is to say in particular the position with respect to the main axis A and the orientation nozzle 24.

The nozzle 24 is supplied with pressurized water via the support pole 22 and the support arm 26.

The support pole 22 thus comprises internal conduits for the circulation of pressurized water (not shown) which open into orifices formed in the outer wall of the support pole 22.

The support arm 26 consists of a tubular element, one end of which is connected to the nozzle 24 which it carries and the other end of the support arm is in fluid communication with the internal ducts of the support pole 22, through an orifice of the support pole 22, at which the support arm 26 is mounted on the support pole 22.

The nozzle 24 is designed so that the water jet 28 is flared and flat. The jet of water 28 emerging from the nozzle 24 is thus a flat jet.

More specifically, the water jet 28 has a triangular main shape, and it is delimited by two straight lines 30 which intersect at a point located in the nozzle 24 and these two straight lines delimit an angle 32, which is the angle of opening of the water jet 28.

Preferably, the value of the opening angle 32 is 10 degrees. It will be understood that the invention is not limited to this single value and that it can also relate to a nozzle 24 producing a jet of water 28 for which the value of the opening angle 32 is between 10 and 40 degrees.

The water jet 28 extends in a plane defined by these two straight lines 30.

During the extraction of the propellant 18, the support pole 22 rotates around the main axis A and translates along this main axis A. The nozzle 24 thus performs a helical trajectory coaxial with the main axis A.

Preferably, the support arm 26 of the nozzle 24 is designed so that the plane in which the water jet 28 exiting the nozzle extends is perpendicular to a direction tangential to this helical trajectory.

Also, according to the embodiment shown in Figure 2, the median axis B of the water jet 28 is inclined relative to a radial direction relative to the main axis A, in the direction of the direction of advance of the support pole 22 during the extraction of propellant 18.

It will be understood that the invention is not limited to this radial orientation of the central axis B and that the central axis B can be inclined differently, in particular, the central axis B can be radial with respect to the axis main a.

This is particularly the case when the installation comprises several nozzles 24, which are carried by several support arms 26, or even when several nozzles 24 are carried by the same support arm 26.

A method of extracting the propellant 18 from the loaded propellant body 12 using such an installation 10 consists in using a nozzle 24 producing a flat jet of water 28 and causing it to travel a helical path coaxial with the main axis of the propellant body. charged propellant 12.

By carrying out this trajectory, the flat water jet 28 erodes part of the propellant 18, over a given thickness 34 and over the entire axial length of the charged propellant body 12.

The helical path of the nozzle 24 has an axial pitch which is defined as a function of the axial extent 36 that propellant is eroded by the water jet 28.

Preferably, when the installation includes a nozzle 24, the value of the axial pitch is equal to this axial extent 36.

According to a variant, the value of the axial pitch is less than this axial extent 36, in order to have an overlap of the passes of the water jet 28 on the propellant 18.

When the installation comprises several nozzles 24, the value of the axial pitch may be less than this axial extent 36.

The method consists in successively implementing several phases during each of which part of the propellant 18 is eroded along said thickness 34, the number of these phases is defined according to the total thickness of propellant 18.

As we said previously, since the water jet 28 is flared and flat, when it impacts the structure 14, its power makes it possible not to damage the latter, even a structure 14 made of composite material.

At the start of a phase, the nozzle 24 is positioned as close as possible to the propellant 18 to be extracted, in order to ensure optimal efficiency of the water jet 28. This positioning is achieved by choosing a support arm 26 with the appropriate dimensions.

During each phase, the pressurized water is conducted to the nozzle 24 to form the water jet 28 flat.

At the same time, the support pole is set in motion, that is to say in rotation around the main axis A and in translation along the main axis A, as represented by the arrows 38 in Figure 2, to give the nozzle 24 and the flat water jet 28 a helical path, along the entire axial length of the charged propellant body 12.

At the end of a phase, part of the propellant 18 has been trimmed according to the erosion thickness 34 defined previously.

An adjustment of the position of the nozzle 24 is carried out between two successive phases, so that the nozzle 24 is again at the best possible distance from the propellant 18 to be extracted for the phase which is going to be implemented.

This adjustment of the position consists in replacing the support arm 26 used during a phase by another support arm adapted to position the nozzle 24 for the following phase.

For example, the support arm 26 used in the later phase has a greater length than the support arm 26 used in the earlier phase.

According to a variant embodiment based on figure 4, the support arm 26 is mounted articulated with respect to the axial end 22A of the support pole 22 around a transverse axis perpendicular to the main axis A.

The support arm 26 is able to pivot around this transverse axis between two extreme positions represented in FIG. 4 by dotted lines.

A first extreme position 26A located in the extension of the axial end 22A of the support pole 22 is inclined by 20 degrees under the main axis A, the second extreme position 26B is inclined by 155 degrees above the axis main A, i.e. a total angular deflection of 175 degrees.

Preferably, the arm 26 oscillates relative to the axial end 22A of the support pole 22 during each extraction phase, in addition to the rotation of the support pole 22 around the main axis A and the translation axis of the support pole 22.

Preferably, for the last phase of the method, the thickness of propellant 18 present on the structure 14 is less than the thickness 34 that the flat jet of water 28 can erode. This makes it possible to extract all of the remaining propellant.

Also, even if the flat jet of water 28 reaches the wall of the structure 14, it cannot damage it, as mentioned previously. The structure 14 can then, depending on the case, be reused or reprocessed.

Also, during all the phases of the extraction process, only a mixture of water and propellant is recovered, which facilitates the subsequent reprocessing of the propellant.

Claims (10)

A method of extracting propellant (18) from a loaded propellant body (12),
said loaded propellant body (12) comprising an elongated structure (14) of main axis A which is an element of revolution around said main axis (A), and inside which said structure, the propellant (18) is located,
the extraction method comprising using at least one nozzle (24) producing a jet (28) of liquid which erodes the propellant (18),
characterized in that the jet (28) of liquid is a flat jet
and in that the nozzle (24) follows a helical path coaxial with the main axis A during the extraction of the propellant (18). Method according to the preceding claim, characterized in that it is implemented in several phases each consisting in eroding the propellant (18) by the flat jet (28), over a predefined thickness (34). Method according to the preceding claim, characterized in that an adjustment of the position of the nozzle 24 is carried out between two successive phases, to bring the nozzle (24) closer to the propellant (18) according to a predefined pitch. A method according to any preceding claim, characterized in that the path traveled by the nozzle (24) has a pitch substantially equal to an axial extent (36) over which propellant is eroded by the flat jet (28). Installation (10) for carrying out a method of extracting propellant (18) from a loaded propellant body (12) according to any one of the preceding claims, which comprises a support pole (22) which is fed in liquid under pressure and which is mobile in translation and rotation along its main axis which coincides with a main axis A of the loaded propellant body (12),
at least one nozzle (24) for projecting a jet of liquid which is carried by the support pole (22),
means (26) for supplying said at least one nozzle (24) with pressurized liquid via the support pole (22),
characterized in that said at least one nozzle (24) is designed to project the liquid in a flat jet (28). Installation (10) according to the preceding claim, characterized in that the said flat jet (28) is delimited by two straight lines (30) which intersect at the level of the nozzle (24) and which delimit an angle (32) of opening of the predefined flat jet (28). Installation (10) according to the preceding claim, characterized in that the value of the said angle (32) of aperture of the flat jet (28) is 10 degrees. Installation (10) according to any one of Claims 5 to 7, characterized in that the said at least one nozzle (24) is carried by a support arm (26) making it possible to adjust the position and the orientation of the nozzle (24) with respect to the support pole (22), and which provides fluid communication between the nozzle (24) and the support pole (22). Installation (10) according to the preceding claim, for implementing a method according to claim 3, characterized in that it comprises a plurality of interchangeable support arms (26) which are capable of being interchanged between two phases of the method, to modify the position of said nozzle (24) with respect to the support pole (22). Installation (10) according to claim 8 or 9, characterized in that each support arm (26) is capable of pivoting relative to the support pole (22) around an axis orthogonal to the main axis (A) during one phase of the process.