Injection molding apparatus and method for automatic cycle to cycle cavity injection

What is claimed is: 1. A method of operating an injection molding system for initiating flow of a fluid material into multiple gates of a mold cavity during an injection cycle, wherein the system includes: a first selected valve comprising a first fluid flow passage having a first gate to the cavity, a first valve pin driven reciprocally along an axial upstream downstream path of travel through the first flow passage by a first actuator between gate open and gate closed positions, one or more downstream valves, each downstream valve comprising a downstream fluid flow passage having a downstream gate to the cavity disposed downstream of the first gate, a downstream valve pin driven reciprocally along an axial upstream downstream path of travel through the downstream fluid flow passage by a downstream actuator between a gate open and a gate closed position the method comprising: detecting, at a downstream detection time, a select property of a flow front of the fluid material flowing downstream at a trigger position within the cavity disposed between the first gate and at least one selected downstream gate wherein, instructing the actuator of the valve associated with the at least one selected downstream gate, or a control valve for that actuator, to withdraw the valve pin from the gate closed position at an instruction time (X) comprising a predetermined open gate target time (X) following the downstream detection time, detecting, at an actual open gate time, withdrawal of the valve pin from the at least one selected downstream gate, determining an adjusted instruction time (X′), for use on a subsequent injection cycle, wherein the determining step comprises decreasing the time of instruction to the valve pin to open on a subsequent injection cycle by an adjustment time equal to any delay in time (Y) between the predetermined open gate target time (X) and the actual open gate time (A). 2. A method according to claim 1 further comprising operating the system described above to cause the actuator of the valve associated with the at least one selected downstream gate to withdraw the valve pin from the gate closed position at the adjusted instruction time (X′) following the downstream detection time. 3. A method according to claim 1 wherein the determining step is performed continuously over a plurality of subsequent injection molding cycles, and wherein the subsequent adjusted instruction time (X″) is determined by increasing or decreasing the adjusted instruction time of a prior cycle by an adjustment time equal to the difference in time between the actual open gate time of the prior cycle and the actual open gate time of the present cycle. 4. A method according to claim 1 the multiple gates of the cavity including an upstream gate and a downstream gate, each gate having an associated actuator and valve pin, and the valve pin being driven by the actuator between a gate closed position (GCP) and a gate open position (GOP), a position sensor associated with the downstream gate that detects withdrawal of the valve pin from the gate closed position toward the gate open position at an actual open gate time (A) and generates an opening signal (S O ) indicative of the actual open gate time (A), a cavity sensor that detects a selected physical condition of arrival (DA) of a flow front of the fluid material at a cavity sensor location (CSL) disposed within the mold cavity between the upstream and downstream gates and generates a detection arrival signal (S DA ) indicative of a time (t DA ) of the detected arrival of the flow front; a controller, communicating with the cavity sensor, position sensor and actuator, the method comprising steps of: during a first injection molding cycle: detecting, by the cavity sensor, the arrival of the flow front of the fluid material in the cavity at the cavity sensor location (CSL) and transmitting the detection signal (S DA ) to the controller, the controller generating and transmitting to the downstream actuator, or a control valve that controls the downstream actuator, a gate open signal (S GO ) at an instruction time comprising a predetermined open gate target time (X) subsequent to the detected arrival time (t DA ), sensing, by the position sensor of the downstream gate, withdrawal of the valve pin and transmitting the opening signal (S O ) to the controller with the actual open gate time (A), the actual open gate time (A) being indicative of a delay time (Y) between the predetermined open gate target time (X) and the actual open gate time (A), the controller generating an adjusted instruction (X′) time comprising the predetermined open gate target time (X) minus the delay time (Y), and during a subsequent injection molding cycle, after the cavity sensor detects and transmits the detection signal (S DA ) to the controller, the controller transmitting to the downstream actuator or its control valve a gate open signal (S GO ) at the adjusted instruction time (X′) subsequent to the detected arrival time (t DA ). 5. A method according to claim 4 comprising: providing, for a plurality of adjacent upstream and downstream gate pairs, the associated position and cavity sensors and performing the method steps during the first and subsequent injection molding cycles, and wherein the subsequent adjusted instruction time (X′) is determined by increasing or decreasing the adjusted instruction time of a prior cycle by an adjustment time equal to the difference in time between the actual open gate time of the prior cycle and the actual open gate time of the present cycle. 6. A method according to claim 4 wherein the upstream gate is a first upstream gate that initiates an initial flow front into the cavity. 7. A method according to claim 4 wherein the actuator associated with the first upstream gate receives a start of cycle signal (S SC ) from the controller or an injection molding machine and in response thereto the actuator initiates opening movement of the valve pin for the first upstream gate. 8. A method according to claim 4 wherein the cavity sensor is a temperature sensor. 9. A method according to claim 4 wherein the position sensor is a hall effect sensor. 10. A method according to claim 4 wherein the position sensor senses movement of an actuator piston that drives the valve pin. 11. A method according to claim 4 wherein the actuator includes a solenoid valve that is activated by the gate open signal (S GO ) to drive the valve pin from the gate closed position (GCP) toward the gate open position (GOP). 12. A method according to claim 4 wherein the actuator is an electronic actuator and the position sensor is an encoder. 13. A method according to claim 4 wherein the method steps are performed continuously over a plurality of subsequent injection molding cycles, and wherein the subsequent adjusted instruction time (X′) is determined by increasing or decreasing the adjusted instruction time of a prior cycle by an adjustment time equal to the difference in time between the actual open gate time of the prior cycle and the actual open gate time of the present cycle. 14. A method according to claim 4 further comprising performing a trial injection molding cycle to determine the predetermined open gate target time (X). 15. A method according to claim 4 wherein the method steps are performed continuously over a plurality of subsequent injection molding cycles, and wherein the subsequent adjusted instruction time (X′) is determined by increasing or decreasing the adjusted instruction time of a prior cycle by an adjustment time equal to the difference in time between