Process and apparatus to make liquid silicone rubber compositions

The invention claimed is: 1. A liquid silicone rubber composition manufacturing assembly, the manufacturing assembly sequentially comprising: (i) a preconditioning assembly for the preparation of a silicone rubber base material; (ii) a primary mass flow meter; (iii) an extruder device, having a first introduction port adapted for the introduction of silicone rubber base material generated in the preconditioning assembly (i), at least one additional introduction port, and an outlet; (iv) a packaging assembly; and additionally comprising: (v) a control unit adapted to receive mass flow information on silicone rubber base material passing through the primary mass flow meter (ii) from the preconditioning assembly (i), to detect any variation from a predetermined mass flow range of values and to compute and control a compensating rate of introduction of the silicone rubber base material into the extruder device (iii) and/or compensating rate(s) of introduction of additional components through the at least one additional introduction port downstream of the first introduction port in the extruder device (iii). 2. The manufacturing assembly of claim 1 , wherein the preconditioning assembly (i) is a compounder for making a silicone rubber base material. 3. The manufacturing assembly of claim 1 , wherein the primary mass flow meter (ii) is based on a Coriolis principle. 4. The manufacturing assembly of claim 1 , wherein the control unit (v) additionally monitors and identifies deviations outside pre-defined tolerances in relative quantities of ingredients and/or time periods when a composition exiting the extruder device (iii) does not meet a targeted product composition. 5. The manufacturing assembly of claim 1 , wherein the control unit (v) additionally monitors for and identifies deviations in flow in one or more of the introduction ports compared to predefined target ranges and is also adapted to trigger and/or generate signals/alarms to cause compensating changes in flow rate therein. 6. The manufacturing assembly of claim 1 , wherein a length/diameter (L/D) ratio of the extruder device (iii) is a value of from 12 to 30. 7. The manufacturing assembly of claim 1 , wherein each additional introduction port is adapted for varying the rate of introduction of its respective ingredient and/or additive into the extruder device (iii) and is able to provide and receive information from the control unit (v). 8. The manufacturing assembly of claim 1 , wherein the extruder device (iii) comprises at least three sections and/or barrels along its length between the introduction port and the outlet. 9. The manufacturing assembly of claim 1 , wherein the packaging assembly (iv) includes hoses, valves, and fixed and/or removable containers. 10. A process for the production of liquid silicone rubber compositions, the process comprising the step of providing the manufacturing assembly of claim 1 . 11. The process in accordance with claim 10 , comprising the steps of: a) making a silicone rubber base composition in the preconditioning assembly (i); b) transferring the silicone rubber base composition from the preconditioning assembly (i) through the primary mass flow meter (ii) and into the extruder device (iii), optionally, introducing additives into the silicone rubber base material being transported through the extruder device (iii) by way of the at least one additional introduction port(s); c) controlling the mass flow of the silicone rubber base material, and optionally additives, in the extruder device (iii) by way of the control unit (v); d) mixing the silicone rubber base material, and optionally additives, in the extruder device (iii) to make a final composition; and e) conveying the final composition from the outlet of the extruder device (iii) to the packaging assembly (iv). 12. The process in accordance with claim 11 , wherein the control unit (v): i) detects any variation from a predetermined mass flow range of the silicone rubber base material when passing through the primary mass flow meter (ii) and if required, computes and controls a compensating rate of introduction of the silicone rubber base material into the extruder device (iii) via the first introduction port and/or the introduction rate(s) of additional components from the at least one additional introduction port(s) in the extruder device (iii); ii) monitors and identifies deviations outside pre-defined tolerances in relative quantities of ingredients and/or time periods when a composition exiting the extruder device (iii) does not meet a targeted product composition; iii) monitors for and identifies deviations in flow in one or more of the introduction ports compared to predefined target ranges and triggers and/or generates signals/alarms to cause compensating changes in flow rate therein; iv) monitors flow rate of the silicone rubber base materials being transported through the primary mass flow meter (ii) from the preconditioning assembly (i) to maintain a pre-determined minimum flow to ensure operational accuracy of the primary mass flow meter (ii); or v) any combination of two or more of i) to iv). 13. The process in accordance with claim 11 , wherein silicone base material and catalyst are mixed to provide a part A composition. 14. The process in accordance with claim 11 , wherein silicone rubber base material and cross-linker and optionally inhibitor are mixed to provide a part B composition. 15. The manufacturing assembly of claim 1 , wherein the control unit (v) detects any variation from a predetermined mass flow range of the silicone rubber base material when passing through the primary mass flow meter (ii) and if required, computes and controls a compensating rate of introduction of the silicone rubber base material into the extruder device (iii) via the first introduction port and/or the introduction rate(s) of additional components from the at least one additional introduction port(s) in the extruder device (iii). 16. The manufacturing assembly of claim 1 , wherein the primary mass flow meter (ii) accounts for density variability when providing mass flow information to the control unit (v). 17. The manufacturing assembly of claim 1 , wherein the extruder device (iii) is a twin screw extruder. 18. The manufacturing assembly of claim 1 , wherein the manufacturing assembly further comprises, between the preconditioning assembly (i) and the primary mass flow meter (ii): a) a screen changer; b) a gear pump; or c) both a) and b). 19. The manufacturing assembly of claim 18 , wherein the manufacturing assembly comprises the screen changer between the preconditioning assembly (i) and the primary mass flow meter (ii). 20. The manufacturing assembly of claim 18 , wherein the manufacturing assembly comprises the gear pump between the preconditioning assembly (i) and the primary mass flow meter (ii).