Aeronautics and astronautics – Spacecraft – Spacecraft formation – orbit – or interplanetary path
Reexamination Certificate
1999-04-27
2001-02-06
Barefoot, Galen L. (Department: 3644)
Aeronautics and astronautics
Spacecraft
Spacecraft formation, orbit, or interplanetary path
Reexamination Certificate
active
06182928
ABSTRACT:
The present invention relates to a method for putting an artificial satellite in geostationary orbit.
When a satellite is intended to be positioned on a high orbit referred to as “geostationary” or “geosynchronous” (with a period of revolution of 24 hours, equal to that of the Earth), the satellite is generally installed on said orbit after having launched the satellite into geostationary transfer orbit, that is to say it then joins the geostationary orbit proper by its own means. This solution has hitherto constituted the best technical/economic compromise both for launch vehicles and for satellites.
However, new launch vehicles which are more powerful now offer the possibility of launching satellites directly into geostationary orbit. Further, the development of electrical propulsion on satellites compromises the possibility, for them, of having them transfer themselves to their final orbit because the thrust levels of electrical propulsion units are very low.
In the medium term, it is therefore probable that the standard procedure will be to launch directly into geostationary orbit. In this case, the final stage (or upper stage) of the launch vehicle needs to position the satellite or satellites directly on the geostationary orbit, then has to join a so-called “graveyard” orbit lying, for example, 300 km above the geostationary orbit, where it is neutralized so as not to create space debris. However, this raises a number of problems.
Firstly, in the case of double launching, the possibility of deploying the supporting structure on the geostationary orbit seems to be precluded. It should therefore be kept together with the upper stage to be moved subsequently to the graveyard orbit at the same time as said upper stage.
Further, after the satellite or satellites have been separated, the upper stage has to be reignited (at least once) to join the graveyard orbit. One of the scenarios for this (Hohman transfer) consists in delivering a first impulse of 5.5 m/s, in waiting about 12 hours, in delivering a second impulse of 5.5 m/s, then in neutralizing the stage. There are of course shorter scenarios, but all require reignition of the upper stage at least once and delivery of at least one impulse greater than or equal to 11 m/s.
What is more, in the event of a serious problem after the upper stage has been sent to the geostationary orbit, the latter may remain “locked” on this orbit (or even explode and create debris which is dangerous to geostationary satellites).
The object of the present invention is to overcome these drawbacks.
To this end, the method for putting in geostationary orbit an artificial satellite placed on said orbit by a space launch vehicle, is noteworthy, according to the invention, by
a) the assembly consisting of the final stage of said launch vehicle and the satellite to be placed on the geostationary orbit is firstly sent directly to a circular orbit, referred to as a graveyard orbit, close to the geostationary orbit but far enough away from the latter to avoid possible interference with space objects lying on the geostationary orbit,
b) the satellite is separated from said final stage, which remains on said graveyard orbit, and
c) the satellite joins the geostationary orbit from said graveyard orbit.
Thus, rather than the launch vehicle (final stage or upper composite of the latter) positioning the satellite directly on the geostationary orbit, it sends it to the so-called graveyard orbit. The upper stage of the launch vehicle deploys the satellite which joins the geostationary orbit by its own means (the work to be done is, however, very modest for the satellite and having an initial orbit different than its final orbit may facilitate its permanent installation). In the case of double launching, the launch vehicle deploys its supporting structure directly on the graveyard orbit (the latter does not therefore need to remain together with the upper stage). Further, since the upper stage (or final stage) is directly on the graveyard orbit, it is no longer necessary to reignite it: all that remains is to neutralize it.
Preferably, said graveyard orbit is at an altitude from a few tens to a few hundreds of kilometers away from the geostationary orbit, in particular lying about 300 kilometers above the geostationary orbit.
Further, advantageously, in step c):
the perigee of the satellite is firstly brought to the altitude of the geostationary orbit using a first impulse;
there is a waiting period of about 12 hours for the satellite to join the perigee of its new orbit, and
the apogee of the orbit of the satellite is brought to the altitude of the geostationary orbit using a second impulse.
What is more, said first and second impulses may then have the value 5.5 m/s and are retroimpulses in the case of a graveyard orbit lying above the geostationary orbit.
REFERENCES:
patent: 3995801 (1976-12-01), Bond
patent: 4691882 (1987-09-01), Young
patent: 5186419 (1993-02-01), Scott
patent: 5595360 (1997-01-01), Spitzer
patent: 5651515 (1997-07-01), Saccoccia et al.
patent: 5927652 (1999-07-01), Lansard
patent: 0640524 (1995-03-01), None
patent: 0673833 (1995-09-01), None
patent: 9731822 (1997-09-01), None
Barefoot Galen L.
Societe Nationale Industrielle et Aerospatiale
Stevens Davis Miller & Mosher L.L.P.
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