Highly compressible open reinforcing cord

The invention claimed is: 1. A cord comprising a single layer made up of N helically wound metal filamentary elements having an outer diameter D, each metal filamentary element describing, when the cord extends in a substantially rectilinear direction, a helical path about a main axis substantially parallel to the substantially rectilinear direction, such that, in a section plane substantially perpendicular to the main axis, a distance between a center of each metal filamentary element and the main axis is equal to half a helix diameter Dh and is substantially constant and identical for all the metal filamentary elements, the metal filamentary elements defining an internal enclosure of a cord of diameter Dv, each metal filamentary element having a diameter Df and a helix radius of curvature Rf defined by Rf=P/(π×Sin(2α)), where P is a pitch of each metal filamentary element expressed in millimeters and α is a helix angle of each metal filamentary element, wherein, with Dh, D, Dv, Df and Rf being expressed in millimeters: 0.10≤ Jr≤ 0.25 9≤ Rf/Df≤ 30, and 1.60≤ Dv/Df≤ 3.20, where Jr=N/(π*(D−Df))×(Dh×Sin(π/N)−(Df/Cos(α×π/180))), α is the helix angle, expressed in degrees, of each metal filamentary element and Dv=Dh−Df. 2. The cord according to claim 1 , wherein 0.14≤Jr≤0.25. 3. The cord according to claim 1 , wherein 9≤Rf/Df≤25. 4. The cord according to claim 1 , wherein 1.70≤Dv/Df≤3.20. 5. The cord according to claim 1 , wherein the helix radius of curvature Rf is such that 4.10 mm≤Rf≤5.30 mm. 6. The cord according to claim 1 , wherein the helix diameter Dh of each metal filamentary element is such that 0.70 mm≤Dh≤1.60 mm. 7. The cord according to claim 1 , wherein Df is such that 0.10 mm≤Df≤0.50 mm. 8. The cord according to claim 1 , wherein Dv is such that Dv≥0.50 mm. 9. The cord according to claim 1 , wherein each metal filamentary element is wound at a pitch P such that 3 mm≤P≤15 mm. 10. The cord according to claim 1 , wherein D≤2.10 mm. 11. The cord according to claim 1 , wherein a ratio K of the pitch P to the diameter Df of each metal filamentary element, P and Df being expressed in millimeters, is such that 19≤K≤44. 12. The cord according to claim 1 , wherein the helix angle α is such that 13°≤α≤30°. 13. The cord according to claim 1 , wherein the cord has a structural elongation As such that As≥1.5%, the structural elongation As being determined by applying the standard ASTM D2969-04 of 2014 to the cord so as to obtain a force-elongation curve, the structural elongation As being equal to elongation, in %, corresponding to a projection onto an elongation axis of intersection between a tangent to a structural portion of the force-elongation curve and a tangent to an elastic portion of the force-elongation curve. 14. The cord according to claim 1 , wherein the cord has, once embedded in a crosslinked standard elastomeric matrix having a modulus in extension at 10% elongation ranging from 5 MPa to 10 MPa, a modulus of elasticity in extension greater than or equal to 100 GPa, the modulus of elasticity in extension at 10% elongation being determined according to the standard ASTM D2969-04 of 2014. 15. A tire comprising the cord according to claim 1 , the cord embedded in an elastomeric matrix.