Method and device for deflection of space debris

Abstract

The invention relates to a method for deflecting space debris comprising steps of: launching (E2) a thruster (2) by means of a sounding rocket (1) at a target altitude close to that of the one or more debris to be deflected. generating (E3) by the thruster a gas cloud (G) above the sounding rocket.

Claims

1. A method for deflecting space debris comprising steps of: launching a thruster by means of a sounding rocket at a target altitude close to that of the one or more debris to be deflected, wherein the thruster comprises a combustion chamber and a nozzle, and the thruster is fixed to the tip of the sounding rocket with the nozzle pointing towards a launch direction of the sounding rocket; generating, by the thruster, a combustion within the combustion chamber causing a downward thrust on the sounding rocket; and emitting, from the nozzle of the thruster, a product of the combustion to generate a gas cloud above the sounding rocket and along a trajectory of the one or more debris.

2. The method as according to claim 1, wherein emitting the product of the combustion to generate the gas cloud comprises a step of orientation and stabilization of the thruster so that the gases coming from the nozzle are correctly oriented.

3. The method according to claim 1, wherein the combustion is generated just before culminating at target altitude, typically from 2 to 5 seconds before culminating at target altitude.

4. The method according to claim 1, wherein the combustion is generated for a period ensuring passage of the debris via the cloud typically over a period of 5 to 15 seconds, typically 10 seconds.

5. The method according to claim 1, wherein the target altitude is typically less by 500 m to 1 km than that of the trajectory of the debris to be avoided.

6. The method according to claim 1, wherein the sounding rocket is launched from the ground or is airborne and wherein the sounding rocket can be consumed or is reusable fully or partially.

7. The method according to claim 1, comprising a determination step of a location of the one or more debris to be deflected and a joint determination step of a launching instant of the rocket as a function of the launching position of the sounding rocket to ensure passage of the one or more debris to be deflected in an orbital zone accessible to the sounding rocket.

8. A device for deflecting space debris comprising: a sounding rocket; and a thruster including a combustion chamber and a nozzle, the thruster being fixed to the tip of the sounding rocket with the nozzle pointing towards a launch direction of the sounding rocket, wherein the thruster is operable to generate a combustion within the combustion chamber causing a downward thrust on the sounding rocket, and to emit a product of the combustion from the nozzle to generate a gas cloud above the sounding rocket and along a trajectory of the space debris.

9. The device according to claim 8, wherein the thruster has solid propulsion or hybrid propulsion.

Description

PRESENTATION OF THE FIGURES

(1) Other features, aims and advantages of the invention will emerge from the following description which is purely illustrative and non-limiting, and which must be considered with respect to the appended drawings, in which:

(2) FIG. 1 schematically illustrates a device for deflecting space debris;

(3) FIG. 2 illustrates steps of a method for deflecting space debris;

(4) FIGS. 3 and 4 schematically illustrate deflection of space debris by means of the deflection device and method according to the invention.

(5) In all figures similar elements bear identical reference numerals.

DETAILED DESCRIPTION OF THE INVENTION

(6) Device and Method for Deflecting Space Debris

(7) FIG. 1 schematically illustrates a device for deflecting space debris comprising a sounding rocket 1 and a thruster 2, secured to the sounding rocket.

(8) A sounding rocket is a rocket describing a sub-orbital trajectory generally used for experimental purposes.

(9) It is specified here that the thruster 2 mentioned is separate from that used for propulsion of the sounding rocket 1 as such.

(10) The sounding rocket 1 comprises several stages 11, 12 (in FIG. 1, the sounding rocket comprises two stages 11, 12).

(11) The thruster 2 is secured to the final stage of the sounding rocket and is directed upwards, i.e., the thruster comprising a combustion chamber 21 and a nozzle 22, the thruster 2 is located with its nozzle 22 pointing upwards, in the launch direction of the sounding rocket.

(12) The thruster 2, in particular with solid propulsion or hybrid propulsion and preferably is a thruster with solid propellants.

(13) As is evident, the useful load of the sounding rocket here is the thruster 2.

(14) Such a device is configured to implement a method for deflecting space debris described herein below and in relation to FIG. 2.

(15) In relation to FIG. 3, there is the event where risk of collision between two catalogued and non-maneuvering debris A, B is announced. It is thought that such risk of collision is unacceptable when its probability is greater than a threshold fixed by the satellite operators or by regulations in effect (standards, rules of good conduct, etc.). So by way of example it is useful to consider that a probability of collision greater than 10.sup.?4 is unacceptable. The respective trajectories of both debris are known with all the more precision since collision is imminent: by way of example, typical forewarning of a collision avoidance manoeuvre is of the order of one to two days.

(16) To avoid collision, the trajectory of one of the two debris, for example debris A (see FIG. 3) will be modified slightly.

(17) Debris A follows an orbital trajectory O.sub.A and can enter into collision with debris B since at any instant the trajectories of both debris A, B intersect.

(18) For this to occur, a sounding rocket will be launched E2 from the surface S of the Earth or from a certain altitude, the sounding rocket is said to be airborne. The sounding rocket follows a trajectory t.

(19) The sounding rocket is launched to reach a culmination altitude, typically less by 500 m to 1 km to that of the trajectory of the debris to be deflected. The culmination altitude of the sounding rocket is located below the trajectory of the debris to be deflected to avoid any risk of collision with this debris.

(20) To ensure passage of debris A in a time frame compatible with the advance notice in the zone accessible to the sounding rocket, the method comprises a step E0 of location of the debris to be deflected and of determination E1, joint, of a launching instant of the sounding rocket as a function of the launching position of the sounding rocket to ensure passage of the one or more debris to be deflected in an orbital zone accessible to the sounding rocket.

(21) The location step E0 implements the means for determining with precision the respective orbits of both debris, by means of radar available at both the national and international levels; however precise they are, these trajectories are subject to uncertainty, both at the level of the position of objects and the provisional date of their eventual collision; by way of example, the position precision is of the order of a kilometer, and the time of transition precision is of the order of a second.

(22) Step E1 is deduced from the precise knowledge of these elements of orbitography and determines with precision the launching instant of the sounding rocket and the main parameters of its trajectory (launching azimuth, culmination altitude, etc.); this step takes into consideration dispersions determined at step E0 to maximize the probability of success of the deflection mission.

(23) Fine adjustment of the position of the thruster relative to the trajectory of the debris can be done by toggling the thruster in the plane of the trajectory of the debris.

(24) Just before culmination (typically from 2 to 5 seconds), just below the target zone, the method comprises a generation step E3 by the sounding rocket of a gas cloud above the sounding rocket.

(25) This generation comprises sub-steps of ignition E31 of the thruster and of stabilization E32 of the latter.

(26) The thruster 2 comprises especially a solid propellant which, once ignited, will generate hot gases coming from its combustion and downwards thrust acting on the sounding rocket. The combustion products escaping via the nozzle 22 of the thruster 2 will form the preferred gas cloud.

(27) So just before culmination, the thruster will create a dense gas cloud G above the sounding rocket.

(28) Debris A, as it passes through this cloud G, undergoes drag force which causes slight slowdown of the latter such that its trajectory is modified, as is its orbital period. After passing through, debris A follows a modified trajectory.

(29) Debris A, as it passes through this cloud G, undergoes drag force which causes slight slowdown of the latter such that its trajectory is modified, as is its orbital period. After passing through, debris A follows a modified trajectory O.sub.A (see also FIG. 4).

(30) Generation of the cloud comprises also a step E4 for stabilisation and orientation of the thruster 2 so that gases coming from the thruster 1 are correctly oriented for debris A to pass through effectively.

(31) Such stabilisation E4 can be performed by gyroscopic stabilisation by setting the sounding rocket in rapid rotation along its main axis (shown by 3 in FIG. 1) or any other device for ensuring that the jet of the thruster is correctly oriented.

(32) The combustion period of the thruster is typically from 5 to 15 seconds, typically 10 seconds to ensure a sufficiently large size of cloud to compensate for any uncertainty as to the real trajectory of debris A.

EXAMPLE OF APPLICATION

(33) The most disturbing catalogued debris are on relatively high and sharply inclined orbits, typically between 700 and 1000 km in altitude, with an inclination greater than 80?. There are two debris in orbit at 850 km in altitude here, 98.6? in inclination. Relevant here is the most critical debris known to date, the 3.sup.rd stage of the Cosmos 3M launcher, of mass of 1.5 tons and a surface of around 12 m.sup.2.

(34) There is also the probable average case of advance warning of 24 h, causing launching 12 hours prior to the collision as announced, i.e., 14 orbits.

(35) If the aim was a change in altitude of perigee of 1 km for debris A, the decrement in speed ?V to be supplied is 0.2569 m/s. But this also causes a change in period of the debris, decreasing by 0.6346 s. This decrease in period, integrated over 14.13 orbits, means that debris A will pass 14.13?0.6346=8.96 s before debris B at the predicted site of their collision. At the orbital speed of 7426.014 m/s (for this altitude), this corresponds to a distance of 66.54 km.

(36) An avoidance criterion of 5 km overall is considered: the deflection imparted to debris A must avoid debris B with a margin of 5 km as they converge (this distance depends naturally on the precision of orbital parameters, though seems conservative since both objects are on secant orbits, and not co-orbiting). The change in speed ?V to be supplied is of the order of 0.2569?5/66.54=0.019 m/s.

(37) A launch base located at high altitude ensures several passages of relevant debris each day. Examples of existing launching bases on the ground are Kiruna (Sweden), Andoya (Norway) or Kodiak (Alaska, USA). In the event of airborne launching, this can be done from any military airport at high latitude.

(38) The sounding rocket, by definition, is not going into orbit, therefore is significantly smaller than a conventional orbital launcher, therefore significantly less expensive also. The aim is a position culminating in precision of the order of a kilometer; the thruster can be ignited before culmination, and this is a value to be optimized. Phasing, in both time and position, between the sounding rocket and the debris is critical; but expected progress linked to novel generations of radars being deployed make preferred precisions credible.

(39) The solid thruster has a fixed nozzle, the direction of its jet and the stability of the upper stage being ensured by gyroscopic stabilization, highly conventional for standard sounding rockets.

(40) The propellant loading of the solid thruster must be optimized as a function of the selected sounding rocket and the preferred size of the cloud, in turn a function of the precision of orbital parameters of debris. A thruster providing a mass flow of the order of 29 kg/s over 45 s is considered, for total mass of 1500 kg. In the case described here, the propellant loading can be greatly decreased, and the mass flow increased by around 30%; a thruster operating for 10 s with mass flow of 38 kg/s is considered therefore; its total mass is of the order of 375 kg.

(41) It is considered that the nozzle is truncated to decrease specific pulse, therefore the ejection speed of gases, which decreases the size of the cloud; the ejection speed considered here is Ve=1500 m/s.

(42) Simplified modeling, given expansion of gases each second in a cone of 5? at iso density in this cone. The volume of such a cone is ?.Math.Ve.sup.3.Math.(tan 5).sup.2/3=27.10.sup.6 m.sup.3. The average density in the cone, produced by 1 second of operation of the thruster, is 38/27.Math.10.sup.6=1.41.Math.10.sup.?6 kg/m.sup.3. The drag generated by this artificial atmosphere is shown by deceleration

(43) $?=\frac{1}{2}\frac{C}{M}?{\mathrm{SV}}^2$
with C the drag coefficient, typically 2.2 in rarefied regime, M the mass of the debris therefore 1500 kg in this example, ? the density in the cloud therefore 1.41.10.sup.?6 kg/m.sup.3 in this example, S the surface of debris A therefore 12 m.sup.2 in this example, and V the relative speed of the debris with respect to the cloud 7576 m/s for the example being considered. Corresponding deceleration is ?=0.712 m/s.sup.2. The action time on debris passing 1500 m from the end of the thruster is t.sub.a=2.Math.Ve.Math.tan 5?/V=0.035 s. Finally the ?V applied to the debris ?V=?.Math.t.sub.a=0.712?0.035=2.5 cm/s, greater than the preferred value is deduced from this.