Sequential injection to multiple mold cavities

What is claimed is: 1. An injection molding apparatus ( 10 a ) comprising an injection molding machine ( 500 ) that injects a selected fluid ( 18 ) to a distribution manifold ( 800 ) that has a distribution channel ( 160 ) that commonly routes the injection fluid ( 18 ) to: one or more first downstream channels ( 166 , 166 a , 166 b ) and associated first gates ( 34 , 34 a , 34 b ) that deliver the injection fluid ( 18 ) to a first cavity ( 300 a ) of a mold system ( 302 , 303 ) and, one or more second downstream channels ( 168 , 168 a , 168 b ) and associated second gates ( 32 , 32 a , 32 b ) that deliver the injection fluid to a second cavity ( 300 b ) of the mold system ( 302 , 303 ), the mold system ( 302 , 303 ) being clamped together under a selected clamp force by a clamp device ( 700 ), the apparatus including a first upstream valve ( 118 ) that enables and disables flow of the injection fluid from the distribution channel ( 160 ) to the first gates ( 34 , 34 a , 34 b ) and a second upstream valve ( 108 ) that enables and disables flow of the injection fluid from the distribution channel ( 160 ) to the one or more second gates ( 32 , 32 a , 32 b ), the apparatus further including a control system ( 20 ) adapted to instruct the first upstream valve ( 118 ) to open or enable flow of the injection fluid ( 18 ) to the one or more first gates ( 34 , 34 a , 34 b ) at a first selected time and to further instruct the second upstream valve ( 108 ) to open or enable flow of the injection fluid ( 18 ) to the one or more second gates ( 32 , 32 a , 32 b ) at a second selected time that is delayed, subsequent or sequential in time relative to the first selected time during the course of an injection cycle, wherein one or more of first and second downstream valves ( 150 a , 150 b ) comprise an actuator ( 50 , 50 b ) interconnected to a valve pin ( 1041 , 1041 a ) having a control surface ( 755 , 1155 ) having a selected configuration adapted to cooperate with a selected complementary surface ( 765 , 1254 ) of a downstream channel ( 166 , 168 ) such that the rate of flow of injection fluid ( 18 ) is controllable continuously over the course of an injection cycle by controlling axial positioning of the control surface ( 755 , 1155 ) of the valve pin relative to the selected complementary surface ( 765 , 1254 ) of a downstream channel ( 166 , 168 ). 2. An apparatus according to claim 1 wherein the second selected time is selected such that a first peak injection fluid force or pressure that occurs within the first cavity ( 300 a ) during an injection cycle occurs at a first peak time that is offset from a second peak time at which a second peak injection fluid force or pressure occurs within the second cavity ( 300 b ) during the injection cycle. 3. Apparatus according to claim 1 wherein the second selected time is selected such that a maximum cumulative fluid force or pressure that occurs within the first and second cavities ( 300 a , 300 b ) during an injection cycle is less than a cumulation of the first and second peak injection fluid forces or pressures. 4. Apparatus according to claim 1 wherein the second selected time is selected such that a first pack phase injection fluid force or pressure that occurs within the first cavity ( 300 a ) during an injection cycle occurs at a first pack phase time that is offset from a second pack phase time at which a second pack phase injection fluid force or pressure occurs within the second cavity ( 300 b ) during the injection cycle. 5. Apparatus according to claim 1 wherein the injection fluid ( 18 ) is injected into the first and second cavities ( 300 a , 300 b ) first under a filling phase pressure or force and subsequently under a pack phase pressure or force, the filling phase pressure or force being substantially less than the pack phase pressure or force. 6. Apparatus according to claim 1 wherein the selected clamp force is selected to be at least equal to a cumulative peak force or pressure exerted by the injection fluid ( 18 ) within the first and second cavities ( 300 a , 300 b ) over the course of an injection cycle. 7. Apparatus according to claim 1 wherein the one or more first downstream valves ( 150 a ) control delivery of the injection fluid ( 18 ) through the first downstream channels ( 166 , 166 a , 166 b ) and associated first gates ( 34 , 34 a , 34 b ) and the one or more second downstream valves ( 150 b ) control delivery of the injection fluid ( 18 ) through the second downstream channels ( 168 , 168 a , 168 b ) and associated second gates ( 32 , 32 a , 32 b ). 8. Apparatus according to claim 1 wherein the second selected time is selected such that a time during the injection cycle at which the injection fluid exerts a peak force or pressure within the first cavity is substantially offset from a time during the injection cycle at which the injection fluid exerts a peak force or pressure within the second cavity. 9. Apparatus according to claim 1 wherein the second selected time is selected such that the selected force of the clamp device is significantly reduced relative to a force equal to a combined peak force or pressure exerted by the injection fluid ( 18 ) within the first and second cavities ( 300 a , 300 b ) where injection fluid ( 18 ) is delivered to the first ( 34 , 34 a , 34 b ) and second ( 32 , 32 a , 32 b ) downstream gates simultaneously. 10. Apparatus according to claim 1 wherein the controller ( 20 ) includes instructions that control timing of opening of the upstream valves ( 108 , 108 s , 118 ), 118 s ) such that the upstream valves ( 108 , 108 s , 118 , 118 s ) are controllably opened to deliver fluid ( 18 ) to and fill the mold cavities ( 300 a , 300 b ) at and over different or staggered times during an injection cycle. 11. Apparatus according to claim 1 wherein the controller ( 20 ) includes instructions that control a degree of openness of the upstream valves ( 108 , 108 s , 118 , 118 s ) at selected times over the course of an injection cycle such that the upstream valves are controllably opened to deliver fluid ( 18 ) to and fill the mold cavities ( 300 a , 300 b ) at different selected rates over the course of an injection cycle. 12. Apparatus according to claim 1 wherein the controller ( 20 ) includes an algorithm that receives fluid pressure data from one or more pressure sensors ( 60 a , 80 a ) that measure fluid pressure at a selected position disposed within an upstream distribution channel ( 162 , 164 ). 13. Apparatus according to claim 1 wherein the controller ( 20 ) includes a memory that stores a predetermined profile of fluid pressures for selected positions at which sensors ( 60 a , 80 a ) measure pressure and the controller further includes instructions that instruct the upstream valves ( 108 s , 118 s ) to open to a degree over the course of an injection cycle that effects a fluid pressure at the selected positions that matches the predetermined profile of pressures over the course of an injection cycle. 14. Apparatus according to claim 1 wherein the controller ( 20 ) is interconnected to and receives fluid pressure data from one or more pressure sensors ( 80 c ) that measure fluid pressure within a downstream fluid channel ( 166 , 168 ) at a position ( 166 ua ) disposed upstream and away from the gates ( 32 , 34 ), the controller ( 20 ) including a memory that stores a predetermined profile of fluid pressures for the upstream and away from the gate posit