Road vehicle convoy control method, and road vehicle convoy

The invention claimed is: 1. A method of controlling a road vehicle convoy, including: a first road vehicle, situated at a head of a convoy and including a wheel set, a plurality of second road vehicles, coupled two by two one behind the other, one of the second vehicles being coupled to the rear of the first vehicle, each second vehicle including: a wheel set, an articulation allowing movement in rotation of at least part of a chassis of the second vehicle relative to at least part of the chassis of the vehicle preceding it about a rotation axis perpendicular to the rolling plane of the convoy; for each articulation, a controllable actuator that mechanically connects the chassis parts that pivot relative to one another about the rotation axis of this articulation, the actuator configured to exert an adjustable moment on this articulation; the method comprising, for each articulation: a) measuring oscillations of an articulation angle about an articulation angle setpoint; b) applying, to the articulation, a moment with an amplitude that varies as a function of the measured oscillations to damp the measured oscillations, the moment being applied to the articulation by controlling the actuator of that articulation; each wheel of the wheel set of each vehicle including a controllable electrical machine for driving the wheel in rotation to propel the vehicle, each of the machines of the same wheel set being controllable independently of other machine or machines of that wheel set; and during the applying b), for each articulation, applying the moment includes, conjointly with control of the actuator of that articulation, control of: the electrical machine of a first wheel of one of the wheel sets that belongs to one of the chassis parts that pivot relative to one another due to this articulation, to increase torque of that first wheel, and simultaneously the electrical machine of a second wheel of the same wheel set to maintain its torque constant or to increase the torque of this second wheel less than the torque of the first wheel to apply the moment to that articulation, in conjunction with the actuator. 2. The method as claimed in claim 1 , wherein, during the applying b): the electrical machine of the first wheel is controlled to increase its rotation speed more rapidly than the rotation speed of the second wheel, and simultaneously the electrical machine of the second wheel is controlled to maintain a zero acceleration of its rotation speed. 3. The method as claimed in claim 1 , wherein, during the applying b), none of the electrical machines of the convoy is controlled to operate as an electricity generator. 4. The method as claimed in claim 1 , further comprising: automatic division of the moment for damping the measured oscillations between: a moment MA equal to X*M that must be applied by the actuator to the articulation, and a moment MR equal to (1−X)*M that must be applied to the articulation with aid of the electrical machines, wherein M is the total moment to be applied to the articulation to damp the oscillations and X is a real number between 0.2 and 1 inclusive when the absolute value of the difference |θ−θ 0 | increases and is equal to zero when the difference |θ−θ 0 | decreases, wherein θ is the angle of the articulation and θ 0 is the articulation angle setpoint; then applying the moment MA to the articulation by controlling the actuator and, conjointly, applying of the moment MR to the articulation by controlling the electrical machines. 5. The method as claimed in claim 4 , wherein the real number X is systematically between 0.2 and 0.9 inclusive when the absolute value of the difference |θ−θ 0 | increases. 6. The method as claimed in claim 1 , further comprising: automatically acquiring the trajectory followed by the first vehicle of the road convoy; and during the applying b), the angle setpoint of each articulation is calculated as a function of the acquired trajectory. 7. The method as claimed in claim 6 , wherein the trajectory is acquired by measuring a magnitude representing steering radius of the first vehicle. 8. The method as claimed in claim 1 , wherein the measuring a) includes calculating the angle setpoint for this articulation and the applying b) includes slaving the actuator of this articulation to the calculated angle setpoint. 9. The method as claimed in claim 1 , wherein the actuator is a cylinder with a controllable damping coefficient configured to brake rotation of the chassis parts that it mechanically connects to one another and incapable of moving in rotation relative to one another those same chassis parts. 10. A non-transitory computer readable storage medium, comprising instructions for execution of the method as claimed in claim 1 when those instructions are executed by an electronic computer. 11. A road vehicle convoy, comprising: a first road vehicle, situated at a head of a convoy; a plurality of second road vehicles, coupled two by two one behind the other, one of the second vehicles being coupled to the rear of the first vehicle, each second vehicle including an articulation allowing movement in rotation of at least part of the chassis of the second vehicle relative to at least part of the chassis of the vehicle preceding it about a rotation axis perpendicular to the rolling plane of the convoy; each of the first and second vehicles including a wheel set; for each articulation of the convoy: a controllable actuator that mechanically connects between its ends the chassis parts that pivot relative to one another about the rotation axis of this articulation, this actuator being configured to exert an adjustable moment on the articulation, a sensor configured to measure oscillations of an angle of this articulation about an articulation angle setpoint, and a control device configured to control the actuator of this articulation to exert on this articulation a moment with an amplitude that varies as a function of the measured oscillations to damp the measured oscillations; wherein: each wheel of each wheel set includes a controllable electrical machine for driving this wheel in rotation to propel the vehicle, each of the machines of the same wheel set being controllable independently of other machine or machines of that wheel set, and for each articulation, the control device is further configured to apply the moment, conjointly with control of the actuator of that articulation, to control: the electrical machine of a first wheel of one of the wheel sets that belongs to one of the chassis parts that pivot relative to one another due to the articulation, to increase the torque of that first wheel, and simultaneously the electrical machine of a second wheel of the same wheel set to maintain its torque constant or to increase the torque of this second wheel less than the torque of the first wheel so as to apply the moment to that articulation, in conjunction with the actuator. 12. The convoy as claimed in claim 11 , wherein: the first and second vehicles are identical and each of these vehicles includes: front and rear chassis parts, each including a wheel set of the vehicle; the articulation, the articulation configured to cause the front and rear parts of this vehicle to pivot relative to one another about its rotation axis; a steering device for steering the wheel set of the front part; the control device is programmed: when it detects that it is situated in the first vehicle, to control the actuator of the articulation of that first vehicle to immobilize the articulation of the first vehicle in a position in which the front and rear parts of the chassis of that vehicle are align