Satellite deorbiting system

The invention claimed is: 1. A satellite stabilization and deorbiting device to stabilize and deorbit a satellite, comprising a pair of coplanar masts, each coplanar mast carrying at least one membrane to form an aerobraking sail, said coplanar masts are fixed to the satellite along non-parallel axes, said coplanar masts form a fixed angle, a first end of each coplanar mast is fixed to the satellite, and a second end of said each coplanar mast is provided with a mass, the fixed angle and each mass being configured to generate a gravity gradient resulting in a restoring torque for aligning a bisectrix of the fixed angle with a satellite velocity vector at any altitude. 2. A satellite comprising the satellite stabilization and deorbiting device as claimed in claim 1 , wherein the bisectrix between the two coplanar masts carrying the aerobraking sails is an axis of a satellite principal system of axes of an inertia matrix of the satellite; and wherein an inertia I z along the bisectrix is between inertia values on other two axes of the satellite principal system of axes. 3. The satellite stabilization and deorbiting device as claimed in claim 1 , wherein said each coplanar mast carries two membranes in a form of panels disposed in a V to form the aerobraking sails. 4. The satellite stabilization and deorbiting device as claimed in claim 3 , wherein the panels are rectangular panels, one of longer sides of each rectangular panel is fixed to said each coplanar mast. 5. The satellite stabilization and deorbiting device as claimed in claim 3 , wherein an angle between the panels on a same coplanar mast is between 70 to 110°. 6. The satellite stabilization and deorbiting device as claimed in claim 3 , wherein the V has a same orientation for the two coplanar masts. 7. A method of sizing the coplanar masts, and determining masses m and an angle α of the satellite as claimed in claim 2 , comprises steps of: determining, by trajectory calculation tools, a minimum effective aerobraking sail area to deorbit the satellite in a predetermined time; dividing the minimum effective aerobraking sail area across said two coplanar masts of length L with an angle 2α between said two coplanar masts; placing a mass m at an end of each coplanar mast; positioning said two coplanar masts at an arbitrary location on the satellite; selecting the satellite principal system of axes such that its axis Z is the bisectrix of an angle between said two coplanar masts; calculating and diagonalizing the inertia matrix of the satellite; reproducing an approach by successive iterations that varies installation locations of said coplanar masts, the lengths of said coplanar masts, the masses m and the angle α, so that: the axis Z of the satellite principal system of axes is also the bisectrix of said coplanar masts; and the inertia I Z on the axis Z of the satellite principal system of axes has an intermediate value between a minimum value and a maximum value on the other two axes of the satellite principal system of axes; and selecting values of the masses m, the lengths of said coplanar masts and the angle α that minimizes a total mass of the aerobraking sails while maintaining robustness of the selected values, such that variations of parameters around the selected values do not change attitudes of the satellite with the aerobraking sails.