Over-molded preform system and method

What is claimed is: 1. A system for forming injection molded articles comprising: a turret including a plurality of core plates, each core plate of the plurality of core plates including a plurality of core pins; a first mold unit configured to form an inner injection molded layer for each of the core plates at a first turret position; and a second mold unit configured to form an outer injection molded layer over each inner injection molded layer for each of the core plates at a third turret position; a first end-of-arm-tooling (EOAT) plate, wherein the first EOAT plate is associated with the second mold unit, configured to be disposed on an axis between the second mold unit and the turret when the first mold unit and the second mold unit are in an open state, and configured to perform at least one of post mold cooling, sprue picking, de-gating, insert loading, part orientation, or assembly in the third turret position while the first mold unit and the second mold unit are in the open state; a second EOAT plate, wherein the second EOAT plate is associated with a fourth turret position, configured to be disposed on an axis facing the turret in the fourth turret position when the first mold unit and the second mold unit are in a closed state, and configured to remove injection molded articles from each of the core plates at the fourth turret position while the first mold unit and the second mold unit are in the closed state; wherein the first mold unit is configured to form the inner injection molded layer for one of the core plates simultaneously with the second mold unit forming the outer injection molded layer over the inner injection molded layer for another of the core plates on an opposing side of the turret as the one of the core plates during which the first mold unit and the second mold unit are in the closed state and configured to provide opposing clamping forces while the inner injection molded layer for other one of the core plates disposed between the opposing core plates at a second turret position is heated; wherein the first EOAT plate is configured to perform at least one of post mold cooling, sprue picking, de-gating, insert loading, part orientation, or assembly for each of the core plates at the third turret position after the first mold unit forms the inner injection molded layer and the second mold unit forms the outer injection molded layer and while the first mold unit and the second mold unit are in the open state; wherein the second EOAT plate is configured to remove injection molded articles from each of the core plates at the fourth turret position while the first mold unit forms the inner injection molded layer and the second mold unit forms the outer injection molded layer and while the first mold unit and the second mold unit are in the closed state; and wherein the first turret position, the second turret position, the third turret position, and the fourth turret position are approximately 90 degrees rotationally offset from an adjacent position. 2. The system of claim 1 , including two hot runners. 3. The system of claim 1 , wherein the first mold unit is configured to be stationary, and the second mold unit is configured to move toward and away from the first mold unit. 4. The system of claim 1 , wherein the first mold unit is connected to a first hot runner, and the second mold unit is connected to a second hot runner. 5. The system of claim 4 , wherein the first hot runner supplies a first material, and the second hot runner supplies a second material. 6. The system of claim 1 , including at least one of a cavity plate and a stripper plate. 7. The system of claim 1 , wherein the plurality of core plates includes four core plates. 8. The system of claim 7 , wherein the turret includes a stripper plate to facilitate ejection of molded articles. 9. The system of claim 1 , wherein the inner injection molded layer comprises polyethylene terephthalate (PET) or a barrier material. 10. The system of claim 1 , wherein the second mold unit includes a cavity plate and a necksplit plate. 11. The system of claim 1 , wherein the second mold unit is configured to provide a plastic material in more than one stage. 12. A method for forming injection molded articles comprising: providing a first mold unit, a second mold unit, and a turret including a plurality of core plates, each core plate of the plurality of core plates including a plurality of core pins, wherein the turret is disposed between the first mold unit and the second mold unit; molding an inner injection molded layer for one of the core plates in a first turret position; rotating the turret so that the one of the core plates is in a second turret position; heating the inner injection molded layer for the one of the core plates; rotating the turret so that the one of the core plates is in a third turret position, the third turret position opposing the first turret position, and another one of the core plates is in the first turret position; molding an outer injection molded layer over the inner injection molded layer for the one of the core plates in the third turret position and an inner injection molded layer for the another one of the core plates in the first turret position, wherein counteracting clamping forces are used with molding of the inner injection molded layer for the another one of the core plates and the outer injection molded layer; providing a first end-of-arm-tooling (EOAT) plate, wherein the first EOAT plate is associated with the second mold unit, configured to be disposed on an axis between the second mold unit and the turret when the first mold unit and the second mold unit are in an open state, and configured to perform at least one of post mold cooling, sprue picking, de-gating, insert loading, part orientation, or assembly while the first mold unit and the second mold unit are in the open state; performing at least one of post mold cooling, sprue picking and demolding, de-gating, insert loading, part orientation, or assembly in the third turret position via the first end-of-arm-tooling plate after the first mold unit forms the inner injection molded layer and the second mold unit forms the outer injection molded layer and while the first mold unit and the second mold unit are in the open state; rotating the turret so that the one of the core plates is in a fourth turret position; providing a second end-of-arm-tooling (EOAT) plate, wherein the second EOAT plate is associated with the fourth turret position, configured to be disposed on an axis facing the one of the core plates in the fourth turret position when the first mold unit and the second mold unit are in a closed state, and configured to remove injection molded articles from the one of the core plates in the fourth turret position while the first mold unit and the second mold unit are in the closed state; and removing molded articles from the one of the core plates at the fourth turret position via the second EOAT plate while the first mold unit forms another inner injection molded layer and the second mold unit, forms another outer injection molded layer and while the first mold unit and the second mold unit are in the closed state. 13. The method of claim 12 , wherein the inner injection molded layer for the another one core plates at the first turret position and the outer injection molded layer over the inner injection molded layer for the one the core plates at the third turret position are molded at substantially the same time. 14. The method of claim 12 , including use of at least one of a cavity plate and a stripper plate. 15. The method