Force-shunting device and mechanical actuator comprising such a device

The invention claimed is: 1. A force-shunting device ( 1 ), comprising: a tube ( 2 ) that extends along a main axis (X 2 ) and that has a substantially cylindrical inner friction wall ( 6 ); a first member ( 3 ) that is slidably mounted within the tube ( 2 ) along the main axis (X 2 ); at least two primary legs ( 5 ) disposed obliquely relative to the main axis (X 2 ), and each of said at least two primary legs including an inner end ( 12 ) attached to the first member ( 3 ), and each of the at least two primary legs ( 5 ) having an outer end forming a primary pad ( 13 ), which is in frictional contact with the inner wall ( 6 ), wherein each said inner end ( 12 ) is arranged upstream from each said primary pad ( 13 ) relative to a first direction parallel to the main axis (X 2 ), such that, when a first external force (EI) is applied along the first direction on the first member ( 3 ) each of said at least two primary legs ( 5 ) rubs or grips by mechanical camming against the inner wall ( 6 ) via each said primary pad ( 13 ), the tube ( 2 ) thus reacting only a fractional force (F 1 ) of the first external force (EI) by rubbing each said primary pad ( 13 ) against the inner wall, or all of the first external force (EI) by mechanical camming of the at least two primary legs ( 5 ); and a second member ( 4 ) that is mounted within the tube ( 2 ) and slidable along the main axis (X 2 ), the second member drivingly connected to the first member ( 3 ), and the second member ( 4 ) is secured to at least one driving element, the driving element drives each said primary pad ( 13 ) so as to reduce the friction of the second member ( 4 ) on the inner wall ( 6 ), under the application of a second external force (E 2 ) on the second member ( 4 ) along the first direction, to unprime the rubbing or mechanical camming of each of said at least two primary legs ( 5 ). 2. The device according to claim 1 , wherein the driving element is designed to drive each said primary pad ( 13 ) away from the inner wall ( 6 ) when the second external force (E 2 ) is applied on the second member ( 4 ). 3. The device according to claim 1 , wherein the second member ( 4 ) forms a ring coaxial with the main axis (X 2 ), the driving element forming a pad ( 14 ) that extends substantially parallel to the main axis (X 2 ), the ring is attached to each of said at least two primary legs ( 5 ) via the driving element. 4. The device according to claim 1 , wherein the driving element is designed to bear against each of the at least two primary legs ( 5 ) in the first direction. 5. The device according to claim 1 , wherein the first member ( 3 ) forms a hollow cylinder that is coaxial with the main axis (X 2 ), the second member ( 4 ) being translatable along the main axis (X 2 ) within the tube ( 2 ), the second member ( 4 ) being provided with two stops defining a translational travel of the second member ( 4 ) relative to the tube ( 2 ), and via which the second member ( 4 ) can translate the first member ( 3 ) along the main axis (X 2 ) relative to the tube ( 2 ). 6. The device according to claim 1 , wherein each of the at least two primary legs ( 5 ) are metallic and elastically deformable and are mounted so as to be able to keep each said primary pad ( 13 ) in contact with the inner wall ( 6 ) by elasticity. 7. The device according to claim 1 , wherein the inner end ( 12 ) of each of the at least two primary legs ( 5 ) comprises an elastic pivot link by which it is attached with the first member ( 3 ), around a pivot axis (X 20 ) that is substantially orthoradial to the main axis ( 3 ), the elastic pivot link making it possible to keep each said primary pad ( 13 ) in contact with the inner wall ( 6 ) by elasticity. 8. The device according to claim 1 , wherein the device comprises at least one secondary leg ( 52 ) arranged obliquely relative to the main axis (X 2 ), the secondary leg ( 52 ) including an inner end ( 12 ) via which it is attached to the first member ( 31 ), and an outer end forming a secondary pad ( 131 ), which is in frictional contact with the inner wall ( 6 ), the inner end ( 12 ) of said at least one secondary leg being arranged downstream from the secondary pad ( 131 ) considering the first direction, such that, when a third external force is applied in opposition with the first direction on the first member ( 3 ), the at least one secondary leg ( 52 ) rubs or grips by mechanical camming against the inner wall ( 6 ) via the secondary pad ( 131 ), the tube thus reacting only a fraction of the third external force by rubbing of the secondary pad ( 131 ) of the at least one secondary leg ( 52 ) against the inner wall ( 6 ), or all of the third external force by mechanical camming of the at least one secondary leg ( 52 ); the second member ( 41 ) including a secondary driving element that is secured with the second member ( 4 ), to drive the secondary pad ( 131 ) so as to reduce the friction of the second member on the inner wall ( 6 ), under the application of a fourth external force on the second member ( 41 ) along a direction opposite the first direction, to unprime the rubbing or mechanical camming of the at least one secondary leg ( 52 ). 9. A mechanical actuator comprising: a force-shunting device ( 1 ) according to claim 1 ; and a jack coupled to the second member ( 4 ) so as to be able to drive the second member ( 4 ) along the main axis (X 2 ) relative to the tube ( 2 ).