184                     History and Science of Knots

          longer and thinner than at the start; hence, when reloaded, and provided all
          loads are less than already imposed, they have a reduced elongation for a given
          load but eventually show complete recovery from this elongation [20, p. 231].

                        Table 1. ELONGATION AND RELAXATION OF ROPE
                             Load 20% of breaking strength [20, p2381

                                           12 mm diam 40 mm diam
                                           sisal rope manila/sisal rope
                    Elongation
                    On reaching load       6.0% 14.2%
                   After 15 min holding load 6.4% 16.2%

                    Relaxation
                    Recovery after release of load
                    15 min                 62.4%       47.5%
                    24 hr                  70.3%       56.0%
                    1000 hr                76.6%       58.5%


                                                         B  D






                    0
                   J



                                            E F
                                           Elongation
             Fig. 2. Load/elongation curves for repeated loadings of a rope. The maximum
             load imposed was 50% of the breaking strength; shaded areas correspond to the
             energy absorption of the rope on the first and last cycle
              When a rope is tensioned and stretches, the energy imparted to or ab-
          sorbed by the rope is equal to the area under the load/elongation curve; it may
          be expressed as metre-Newtons or Joules. As seen in Fig. 1, little energy is
          absorbed by the rope when the load is light, that is, very little work is needed
          for the early stretch, but as the load is increased, the energy absorbed or the
          work needed increases more and more rapidly. Determination of the energy