Apparatus and process for secondary encapsulation of solid inclusions using the rotary die process

What is claimed is: 1. A method comprising: introducing a continuous first film on a first rotating encapsulation die comprised of a first series of cavities; introducing a continuous second film on a second rotating encapsulation die comprised of a second series of cavities; wherein the first series of cavities and the second series of cavities are synchronized to align with each other as the first rotating encapsulation die and the second rotating encapsulation die turn, and wherein each cavity in the first series of cavities and in the second series of cavities forming one half of a total cavity for a capsule to be formed; mechanically dispensing at least one solid inclusion from a dispensing tube, the dispensing tube integrated into a wedge positioned between the continuous first film and the continuous second film of the first rotating encapsulation die and of the second rotating encapsulation die, respectively, the dispensing tube being positioned off-center in the wedge and aligned with a first row of cavities in the first rotating encapsulation die and a second row of cavities in the second rotating encapsulation die; trapping the at least one solid inclusion between the continuous first film, in a section of the continuous first film aligned over a die cavity, and the wedge to form a first half of a capsule within a cavity of the first rotating encapsulation die; rotating the first rotating encapsulation die and the second rotating encapsulation die in counter directions to contact the continuous first film and continuous second film between the first rotating encapsulation die and the second rotating encapsulation die to form a closed capsule; and simultaneously fusing a first pair of edges of the continuous first film and a second pair of edges of the continuous second film between the cavity of the first rotating encapsulation die and a cavity of the second rotating encapsulation die to hermetically seal the at least one solid inclusion into the closed capsule, wherein the mechanically dispensing at least one solid inclusion comprises: retracting a dispensing plunger in the dispensing tube, the dispensing tube being positioned adjacent to the feeding tube; transferring the at least one solid inclusion from the feeding tube into the dispensing tube through gravity; timing the dispensing plunger to eject the at least one solid inclusion from the dispensing tube with the rotation of the first rotating encapsulation die such that the at least one solid inclusion is trapped between the continuous first film and the wedge in the cavity of the first rotating encapsulation die to form a first half of a capsule; and ejecting the at least one solid inclusion. 2. The method of claim 1 , further comprising mechanically dispensing a liquid through the wedge in synchrony with the rotating of the first rotating encapsulation die and of the second rotating encapsulation die to allow for timely trapping of the dispensed liquid with the at least one solid inclusion within the closed capsule. 3. The method of claim 1 , wherein the mechanically dispensing at least one solid inclusion comprises: retracting an actuator positioned at a top of the dispensing tube to load a plurality of solid inclusions into the dispensing tube from a hopper holding a reservoir of solid inclusions; timing the actuator to extend and eject the at least one solid inclusion from the dispensing tube in synchrony with the rotation of the first rotating encapsulation die such that the at least one solid inclusion is trapped between the continuous first film and the wedge in the cavity of the first rotating encapsulation die to form a first half of a capsule; extending the actuator a distance equivalent to a number of solid inclusions to be placed in the capsule; and ejecting the number of solid inclusions to be placed in the capsule. 4. The method of claim 3 , wherein the actuator is selected from the group consisting of electromagnetic, rotary screw driven, cam driven, hydraulically driven, and pneumatically driven. 5. The method of claim 1 , wherein the mechanically dispensing further comprises filling liquid into the dispensing tube to displace air. 6. The method of claim 5 , wherein the liquid is supplied from a liquid hopper such that the level of the liquid in the dispensing tube is equivalent to the level of the liquid in the hopper. 7. The method of claim 1 , wherein the loading is continuous. 8. A system comprising: a first rotating encapsulation die comprising a first set of die cavities; a continuous first film on the first rotating encapsulation die; a second rotating encapsulation die comprising a second set of die cavities; a continuous second film on the second rotating encapsulation die; a wedge positioned between the first rotating encapsulation die and the second rotating encapsulation die; a dispensing tube integrated into the wedge and positioned off-center in the wedge and aligned with a first row of cavities in the first rotating encapsulation die and a second row of cavities in the second rotating encapsulation die for dispensing at least one solid inclusion; a mechanical dispensing mechanism and a synchronization mechanism for synchronizing the rotation of at least one of the first rotating encapsulation die or the second rotating encapsulation die with the mechanical dispensing of the at least one solid inclusion such that the at least one solid inclusion is timely trapped between the continuous first film and the wedge in a cavity within the first set of die cavities to form a first half of a capsule; and a dispensing tube integrated into the wedge and positioned adjacent to a feeding tube, the dispensing tube comprising a dispensing plunger for controlling the number of solid inclusions dispensed from the feeding tube into the dispensing tube through gravity. 9. The system of claim 8 , wherein the mechanical dispensing mechanism comprises an actuator positioned at a top of the dispensing tube for loading the dispensing tube and ejecting the at least one solid inclusion in synchrony with the rotation of at least one of the first rotating encapsulation die or the second rotating encapsulation die such that the at least one solid inclusion gets trapped between at least one of the continuous first film or the continuous second film and the wedge in a cavity within at least one of the first set of die cavities or the second set of die cavities to form a first half of a capsule. 10. The system of claim 9 , wherein the actuator is selected from the group consisting of electromagnetic, rotary screw driven, cam driven, hydraulically driven, and pneumatically driven. 11. The system of claim 1 , further comprising a liquid hopper for supplying liquid to the dispensing tube to displace air upon ejection of the at least one solid inclusion. 12. The system of claim 8 , wherein the dispensing tube further comprises liquid above the plurality of solid inclusions, wherein the dispensing tube is connected to the mechanical dispensing mechanism, the mechanical dispensing mechanism being a pump for dispensing the at least one solid inclusion in synchrony with the rotation of at least one of the first rotating encapsulation die or the second rotating encapsulation die such that the at least one solid inclusion gets trapped between at least one of the continuous first film or the continuous second film and the wedge in a cavity within at least one of the first set of die cavities or the second set of die cavities to form a first half of a capsule. 13. The system of claim 12 , wherein the pump is a positive displacement pump. 14. The system of claim