Polymerisation process

The invention claimed is: 1. Ionic polymerisation cascade process for the polymerisation of a liquid monomer(s) containing reaction mixture in a polymerisation system comprising a first homogenising prepolymerisation unit (“HPPU”) and a second polymerisation unit in series wherein the polymerisation reaction starts in the HPPU and continues in the second polymerisation unit consisting of a polymerisation loop, a coolant loop and a heat exchanger reactor system (“HERS”) which is shared amongst the polymerisation loop and the coolant loop, characterised in that the HERS has a ratio of surface area to reaction mixture volume (“S/V” expressed in m 2 /m 3 ) higher than 10 and lower than 450, and the HPPU has a ratio of surface area to reaction mixture volume (“S/V” expressed in m 2 /m 3 ) higher than 600, and the ratio between the residence time of the reaction mixture in the first homogenising prepolymerisation unit and the residence time of the reaction mixture in the second polymerisation unit is comprised between 0.01% and 5%. 2. Ionic polymerisation cascade process according to claim 1 wherein the residence time of the reaction mixture in the HPPU reactor (which is calculated by dividing the volume of the HPPU reactor by the volumetric feed rate) is in the range from 0.5 sec to 200 seconds. 3. Ionic polymerisation cascade process according to claim 1 wherein the residence time of the reaction mixture in the polymerisation loop (which is calculated by dividing the volume of the polymerisation loop reactor by the volumetric feed rate) is in the range from 10 sec to 100 min. 4. Ionic polymerisation cascade process according to claim 1 wherein the homogenising prepolymerisation unit (“HPPU”) reactor is a fluidic device with fluid channels the smallest dimension of which is in the range of from 1.0 millimeter to 3.0 millimeters. 5. Ionic polymerisation cascade process according to claim 1 wherein the homogenising prepolymerisation unit (“HPPU”) reactor is a fluidic device with fluid channels wherein the characteristic dimension of such fluidic device is defined as the smallest dimension perpendicular to the reaction mixture flow direction, and said characteristic dimension is comprised between 50 microns and 8.0 millimeters. 6. Ionic polymerisation cascade process according to claim 1 wherein the homogenising prepolymerisation unit (“HPPU”) reactor is a fluidic device which includes at least one reaction mixture passage and one or more thermal control passages, the one or more thermal control passages being positioned and arranged within two volumes each bordered by a wall, the walls being planar and parallel to one another, the reaction mixture passage positioned between said planar walls and defined by said planar walls and walls extending between said planar walls being in the micrometer to millimeter range. 7. Ionic polymerisation cascade process according to claim 1 wherein the homogenising prepolymerisation unit (“HPPU”) reactor is characterised by a mixing performance characterised by a UV transmission value which is greater than 80% according to the Villermaux test (measured by the method described in Villermaux J., et al. “Use of Parallel Competing Reactions to Characterize Micro Mixing Efficiency,” AlChE Symp. Ser. 88 (1991) 6, p. 286). 8. Ionic polymerisation cascade process according to claim 1 wherein the HPPU reactor is characterised by a volumetric heat transfer coefficient (expressed in MW/m 3 .K) higher than 0.5, and lower than 3.0. 9. Ionic polymerisation cascade process according to claim 1 wherein the second stage process is an ionic polymerisation loop process in the second polymerisation unit which comprises a polymerisation loop, a coolant loop and a heat exchanger reactor system (“HERS”) which is shared amongst the polymerisation loop and the coolant loop wherein the polymerisation loop comprises a polymer withdrawal system and a reaction mixture piping system which comprises a circulating pump and which is connected to an inlet and an outlet of said HERS and wherein the coolant loop comprises a coolant piping system connected to an inlet and an outlet of said HERS, characterised in that 1. the HERS comprises at least one section in which both the reaction mixture and the coolant are circulated, 2. the said HERS' section(s) comprises “n” (n being an integer superior or equal to 1) Parallelepipedic channel(s) wherein the reaction mixture is circulated and “n+1” passages wherein the coolant is circulated, 3. the flow paths of the reaction mixture in the “n” channel(s) of a section are unidirectionally parallel, 4. the flow paths of the coolant in the “n+1” passages of a section are unidirectionally parallel to the reaction mixture flow paths, and 5. the coolant is not in direct contact with the reaction mixture. 10. Ionic polymerisation cascade process according to claim 9 wherein the temperature difference of the coolant between any point within the coolant side of the HERS is lower than 3° C. 11. Ionic polymerisation cascade process according to claim 1 wherein the second stage process is an ionic polymerisation loop process in the second polymerisation unit which comprises a polymerisation loop, a coolant loop and a heat exchanger reactor system (“HERS”) which is shared amongst the polymerisation loop and the coolant loop wherein the polymerisation loop comprises a polymer withdrawal system and a reaction mixture piping system which comprises a circulating pump and which is connected to an inlet and an outlet of said HERS and wherein the coolant loop comprises a coolant piping system connected to an inlet and an outlet of said HERS, characterised in that 1. the HERS comprises at least one section in which both the reaction mixture and the coolant are circulated, 2. the said HERS' section(s) comprises “n” (n being an integer superior or equal to 1) Parallelepipedic channel(s) wherein the reaction mixture is circulated and “n+1” passages wherein the coolant is circulated and at least partially evaporated, 3. the flow paths of the reaction mixture in the “n” channel(s) of a section are unidirectionally parallel, 4. the coolant is an evaporative coolant, 5. the flow paths of the evaporative coolant in the “n+1” passages of a section are unidirectionally parallel to the reaction mixture flow paths, 6. the coolant is not in direct contact with the reaction mixture, and 7. the coolant piping system comprises a coolant liquefaction system. 12. Process according to claim 9 wherein the HERS is a platular reactor which comprises at least “x” sections, x being an integer superior or equal to 2, the said sections being parallel and in series and side by side, wherein the flow path of the reaction mixture in a section of the HERS is opposite to the flow path of the reaction mixture in the next section (“serpentine flow path”), wherein the flow path of the reaction mixture in the channel(s) of the first section is ascending and the flow path of the reaction mixture in the channel(s) of the last section is descending, wherein the direction of the flow paths of the reaction mixture in the channel(s) of the sections of the HERS are vertical, and the direction of the flow paths of the coolant in the passages of the sections of the HERS are vertical and ascending, and wherein a section shares its last coolant passage with the first coolant passage of the next section. 13. Process according to claim 12 wherein the number of sections “x” is pair and is superior to or equal to 4. 14. Process according to claim 12 wherein each HERS' section comprises “n” (n being an integer comprised between 4 and 16) Parallelepipedic