Lead-lag damper integrated inside a blade of a rotor

What is claimed is: 1. A lead-lag damper for a blade of a rotor of a rotary wing aircraft, the rotor being provided with a hub that is driven in rotation, the lead-lag damper comprising: a longitudinal axis; a ball-joint connection for connecting to the hub; two strength members, one of the two strength members is an inner strength member and being provided with a cage in which the ball-joint connection is arranged, the other of the two strength members is an outer strength member and being securable to the blade; and a member made of elastomer material that is arranged between the inner strength member and the outer strength member; each of the two strength members and the elastomer material member being arranged on opposite sides of the cage; the inner strength member and the outer strength member each having at least two walls and at least one secondary partition in contact with the elastomer material member and configured so as to increase contact areas between the elastomer material member and the two strength members, the inner strength member including at least one main partition connecting together the at least two walls of the inner strength member; wherein the at least one secondary partition of the inner strength member and the at least one secondary partition of the outer strength member subdivide the elastomer material member into a plurality of distinct blocks of elastomer material, the blocks being situated between the at least one secondary partition of the inner strength member and the at least one secondary partition of the outer strength member or between the at least one main partition and one of the at least one secondary partition of the inner strength member and the at least one secondary partition of the outer strength member so that relative movements between the two strength members as a result of movements of the blade are damped by deformations of the elastomer material member, the lead-lag damper being arrangeable at least in part inside the blade. 2. The lead-lag damper according to claim 1 , wherein the two strength members and the elastomer material member extend, at least along the longitudinal axis, beyond a central zone in which the cage is situated, the central zone longitudinally occupying a length not less than the length of the cage. 3. The lead-lag damper according to claim 2 , wherein the lead-lag damper includes along the longitudinal axis an upstream zone situated upstream from the central zone, and a downstream zone situated downstream from the central zone, the two strength members arranged in the upstream, central, and downstream zones and the elastomer material member arranged in at least the upstream and downstream zones. 4. The lead-lag damper according to claim 2 , wherein the lead-lag damper includes along the longitudinal axis an upstream zone situated upstream from the central zone, and a downstream zone situated downstream from the central zone and wherein the elastomer material member is not arranged in the central zone. 5. The lead-lag damper according to claim 4 , wherein the inner strength member has fins arranged in the central zone so as to dissipate heat generated in the ball-joint connection. 6. The lead-lag damper according to claim 1 , wherein the outer strength member includes at least one main partition connecting together the at least two walls of the outer strength member, the blocks of the elastomer material member being situated between the at least one secondary partition of the inner strength member and the at least one secondary partition of the outer strength member, or else between one of the at least one main partition of the inner and outer strength members and one of the at least one secondary partition of the inner strength member and the at least one secondary partition of the outer strength member. 7. The lead-lag damper according to claim 1 , wherein the at least two walls of the outer strength member are connected together via the inner strength member and the elastomer material member. 8. The lead-lag damper according to claim 1 , wherein the outer strength member includes at least one main partition, wherein the elastomer material member has at least two distinct blocks of the plurality of distinct blocks of elastomer material, each block adhering to at least one wall of the at least two walls of the inner and outer strength members or to the at least one main partition of the at least one secondary partition of the inner strength member and to at least one wall of the at least two walls or to one of the at least one main partition and the secondary partition of the outer strength member. 9. The lead-lag damper according to claim 1 , wherein at least one block of the plurality of distinct blocks of the elastomer material member is arranged between the inner strength member and the outer strength member such that the at least one block is of constant section as defined perpendicularly to a middle line of the block. 10. The lead-lag damper according to claim 1 , wherein at least one block of the plurality of distinct blocks of the elastomer material member is arranged between the inner strength member and the outer strength member in such a manner that the at least one block has a varying section as defined perpendicularly to a middle line of the block so that the at least one block is stressed uniformly during the relative movements between the inner strength member and the outer strength member. 11. The lead-lag damper according to claim 1 , wherein at least one block of the elastomer material member includes an insert embedded in the block so as to improve the stiffness of the block. 12. The lead-lag damper according to claim 1 , wherein the outer strength member includes at least one main partition, wherein the two strength members include at least one wall of the at least two walls of the inner strength member and of the at least two walls of the outer strength member and/or at least one partition of the at least one main partition and of the at least one secondary partition of the inner strength member and of the at least one main partition and of the at least one secondary partition of the outer strength member parallel to a transverse axis of the lead-lag damper, the transverse axis being perpendicular to the longitudinal axis. 13. The lead-lag damper according to claim 1 , wherein the outer strength member includes at least one main partition, wherein the two strength members comprise at least one wall of the at least two walls of the inner strength member and of the at least two walls of the outer strength member and/or at least one partition of the at least one main partition and of the at least one secondary partition of the inner strength member and of the at least one main partition and of the at least one secondary partition of the outer strength member constituted by shapes that are not planar. 14. The lead-lag damper according to claim 1 , wherein the elastomer material member is distributed on the opposite sides of the cage, where the ball-joint connection has a center of rotation and the cage has a center corresponding to the center of rotation of the ball-joint connection, the elastomer material member is configured in such a manner that forces induced by the deformations of the elastomer material member as a result of the relative movements of the two strength members are distributed uniformly on the opposite sides of the cage, at least relative to a vertical first plane perpendicular to the longitudinal axis passing through the center of the cage. 15. The lead-lag damper according to claim 1 , wherein the elastomer material memb