Method for alleviating and protecting loads for an aircraft

What is claimed is: 1. A method for alleviating and protecting loads of a lifting surface of an aircraft comprising a control unit in which is stored an acceptable interval of tolerance of shapes for the lifting surface, the lifting surface comprising a fixed proximal end and a free distal end and being equipped with at least one control surface and a maneuvering system provided to displace the control surface relative to the lifting surface, the lifting surface also comprising a distal sensor fixed to a structure of the lifting surface in a vicinity of its distal end and a proximal sensor fixed to the structure of the lifting surface in the vicinity of its proximal end, each sensor being connected to a control unit and configured to measure a dimensional characteristic linked to distortion of the lifting surface, the method for alleviating and protecting loads comprising: a first process and a second process, wherein the first process comprises, for the control unit, assigning a first value to a strain attribute if the lifting surface is not placed under controlled strain or a second value to the strain attribute if the lifting surface is placed under controlled strain, and wherein the second process comprises at least: an acquisition step during which each sensor acquires characteristic data linked to the distortion to which the lifting surface is subjected and transmits these data to the control unit; a computation step during which the control unit determines, from the duly transmitted data, a set of values characterizing a shape of the lifting surface; a first comparison step during which the control unit analyzes the value of the strain attribute; if the value of the strain attribute is equal to the second value, the process is continued by a second comparison step during which the control unit compares the set of values characterizing shape of the lifting surface to values of the tolerance interval associated with the lifting surface; if the set of values characterizing the shape lies within the interval, the process loops to the acquisition step; and if the set of values characterizing the shape is outside of the interval, the process comprises an alleviation step during which the control unit triggers an activation of the maneuvering system to displace the control surface from an initial position, in order to alleviate the loads on the lifting surface. 2. The method according to claim 1 , comprising, after the alleviation step, a timer step during which position of the control surface remains held for a defined time, then a return step during which the control unit triggers an activation of the maneuvering system to displace the control surface, in order to revert to the initial position. 3. The method according to claim 2 , wherein the timer step is 5 seconds. 4. The method according to claim 1 , wherein the second comparison step is followed, when the set of values characterizing the shape lies within the interval, by a step of computation of the gradient during which the control unit computes a gradient between the current set of shape values and a prior set of shape values, then by a fourth comparison step during which the control unit compares the gradient to a set of threshold values and if the gradient is below the threshold, the process loops to the acquisition step and if the gradient is above the threshold, the process is continued by the alleviation, timer and return steps. 5. The method according to claim 1 , wherein the second process comprises: an instruction substep during which a maneuvering order is delivered; a transmission substep during which the maneuvering order is transmitted to a flight computer of the aircraft; and a maneuvering substep during which the flight computer controls the maneuver corresponding to the maneuvering order. 6. The method according to claim 1 , wherein the aircraft comprises an incidence probe arranged at a nose of the aircraft, and wherein the first process comprises: a substep of estimation of a turbulence during which the control unit estimates a value of an incidence angle linked to a disturbance due to the wind; an additional comparison substep during which the control unit compares the duly estimated value of the incidence angle to a threshold value; if the value of the incidence angle is below the threshold value, the first value is assigned to the value of the strain attribute; and if the value of the incidence angle is above the threshold value, the second value is assigned to the value of the strain attribute.