Polymerisation unit and polymerisation process

The invention claimed is: 1. Polymerisation unit for ionic polymerisation of a liquid monomer(s) containing reaction mixture, for example of isobutylene, comprising a polymerisation loop and 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 reaction mixture piping system connected to an inlet and an outlet of said HERS, the coolant loop comprises a coolant piping system connected to an inlet and an outlet of said HERS, the reaction mixture piping system comprises a circulating pump and the polymerisation loop comprises a polymer withdrawal system, characterised in that 1. the HERS comprises at least one section, 2. the said HERS' section(s) comprises “n” (n being an integer superior or equal to 1) parallelepipedic channel(s) for the reaction mixture and “n+1” passages for the coolant, 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 and wherein the coolant is an evaporative coolant and the coolant piping system comprises a coolant liquefaction system. 2. Unit according to claim 1 wherein the HERS is a platular reactor. 3. Unit according to claim 1 wherein the HERS comprises at least “x” sections, x being an integer superior or equal to 2, the said sections being parallel and in series. 4. Unit according to claim 3 wherein a section shares its last coolant passage with the first coolant passage of the next section. 5. Unit according to claim 3 wherein the number of sections “x” is pair and is superior to or equal to 4. 6. Unit according to claim 3 wherein each HERS' section comprises “n” (n being an integer superior or equal to 1) parallelepipedic channels for the reaction mixture and “n+1” passages for the coolant, wherein “n” is comprised between 4 and 16. 7. Unit according to claim 1 wherein the dimensions of the reaction mixture parallelepipedic channels are characterised by a first dimension (“height”) comprised between 2 and 10 m, and a second dimension (“depth”) comprised between 0.1 and 3 m, and a third dimension (“width”) comprised between 2 and 50 mm. 8. Unit according to claim 1 wherein the passages for the coolant are coolant parallelepipedic channels and wherein dimensions of the coolant parallelepipedic channels are characterised by a first dimension (“height”) comprised between 2 and 10 m, and a second dimension (“depth”) comprised between 0.1 and 3 m, and a third dimension (“width”) comprised between 1 and 30 mm. 9. Unit according to claim 7 wherein the heights of the coolant parallelepipedic channels are identical to the heights of the reaction mixture parallelepipedic channels, the depths of the coolant parallelepipedic channels are identical to the depths of the reaction mixture parallelepipedic channels, and the width of the coolant channels (W-Cool) are smaller than the width of the reaction mixture channels (W-Reac). 10. Unit according to claim 1 wherein the ratio between the coolant channels volume and the reaction mixture channels volume in the HERS is lower than 0.8. 11. Unit according to claim 1 wherein the distance between the reaction mixture outlet of the HERS and the reaction mixture inlet of the HERS is lower than 5m. 12. Unit according to claim 1 wherein a reaction mixture junction zone connects the “n” parallelepipedic channels for the reaction mixture feed of a section of the HERS to the “n” parallelepipedic channels for the reaction mixture feed of the next section of the HERS. 13. Unit according to claim 1 wherein the HERS is characterised by a ratio of surface area to reaction mixture volume (“S/V” expressed in m2/m3) higher than 10, and lower than 750.