IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0328457
(2002-12-23)
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발명자
/ 주소 |
- Doyle,Mark
- Galati,Vito
- Firisin,Wesley D.
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출원인 / 주소 |
- Synventive Molding Solutions, Inc.
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
17 인용 특허 :
57 |
초록
▼
In an injection molding machine having upstream and downstream channels communicating with each other for delivering fluid material to one or more mold cavities, apparatus for controlling delivery of the melt material from the channels to the one or more mold cavities, each channel having an axis, t
In an injection molding machine having upstream and downstream channels communicating with each other for delivering fluid material to one or more mold cavities, apparatus for controlling delivery of the melt material from the channels to the one or more mold cavities, each channel having an axis, the downstream channel having an axis intersecting a gate of a cavity of a mold, the upstream channel having an axis not intersecting the gate and being associated with an upstream actuator interconnected to an upstream melt flow controller disposed at a selected location within the upstream channel, the apparatus comprising a sensor for sensing a selected condition of the melt material at a position downstream of the upstream melt flow controller; an actuator controller interconnected to the upstream actuator, the actuator controller comprising a computer interconnected to a sensor for receiving a signal representative of the selected condition sensed by the sensor, the computer including an algorithm utilizing a value indicative of the signal received from the sensor as a variable for controlling operation of the upstream actuator; wherein the upstream melt flow controller is adapted to control the rate of flow of the fluid material at the selected location within the upstream channel according to the algorithm.
대표청구항
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What is claimed is: 1. In an injection molding apparatus having upstream and downstream channels communicating with each other for delivering fluid material to one or more mold cavities, apparatus for controlling delivery of the melt material from the channels to the one or more mold cavities, each
What is claimed is: 1. In an injection molding apparatus having upstream and downstream channels communicating with each other for delivering fluid material to one or more mold cavities, apparatus for controlling delivery of the melt material from the channels to the one or more mold cavities, each channel having an axis, the downstream channel having an axis intersecting a gate of a cavity of a mold, the upstream channel having an axis not intersecting the gate and being associated with an upstream actuator interconnected to an upstream melt flow controller disposed at a selected location within the upstream channel, the apparatus comprising: A sensor for sensing a selected condition of the melt material at a position downstream of the upstream melt flow controller; An actuator controller interconnected to the upstream actuator, the actuator controller comprising a computer interconnected to a sensor for receiving a signal representative of the selected condition sensed by the sensor, the computer including an algorithm utilizing a value indicative of the signal received from the sensor as a variable for controlling operation of the upstream actuator; Wherein the upstream melt flow controller comprises a pin controllaby positionable at a plurality of positions by the upstream actuator to control the rate of flow of the fluid material at the selected location within the upstream channel according to the algorithm. 2. Apparatus of claim 1 further comprising a downstream melt flow controller movable by a downstream actuator between open flow and closed flow positions within the downstream channel. 3. Apparatus of claim 2 wherein the downstream actuator is interconnected to the actuator controller, the algorithm utilizing the value indicative of the signal received from the sensor as a variable to control movement of the downstream melt flow controller between the open flow and closed flow positions. 4. Apparatus of claim 1 wherein the melt flow controller is adapted to create a gap of controllably variable size within the upstream channel, the melt flow controller being movable to increase the size of the gap and the rate of flow upon upstream movement of the melt flow controller. 5. Apparatus of claim 1 wherein the melt flow controller is adapted to create a gap of controllably variable size within the upstream channel, the melt flow controller being movable to decrease the size of the gap and the rate of flow upon downstream movement of the melt flow controller. 6. Apparatus of claim 1 wherein the melt flow controller comprises a pin having an axis slidably mounted for back and forth movement of the pin through the upstream channel; the pin having a bulbous protrusion along its axis, the bulbous protrusion having a smooth surface extending between an upstream end and a downstream end of the bulbous protrusion and a maximum diameter circumferential surface intermediate the upstream and downstream ends of the bulbous protrusion; the complementary surface of the upstream channel being complementary to the maximum diameter circumferential surface of the bulbous protrusion of the pin; the pin being slidable to a position within the upstream channel such that the maximum diameter circumferential surface of the bulbous protrusion mates with the complementary interior surface portion of the upstream channel. 7. Apparatus of claim 1 wherein the melt flow controller comprises a rotary valve. 8. Apparatus of claim 1 wherein the actuator comprises a mechanically movable member interconnected to the melt flow controller, the mechanically movable member being controllably drivable for movement through a predetermined path of travel according to the algorithm. 9. Apparatus of claim 8 wherein the mechanically movable member is drivable by hydraulic, pneumatic or electrical energy, force or power. 10. Apparatus of claim 2 wherein, during an injection cycle having a start point, an end point and an intermediate time duration, the algorithm includes a first set of instructions for moving the downstream melt flow controller to the open flow position at the start point and to the closed flow position at the end point and a second set of instructions for moving the upstream controller to a plurality of positions that control the rate of flow of fluid material during the intermediate time duration, the first and second sets of instructions utilizing the value indicative of the signal received from the sensor as a variable for controlling operation of the upstream and downstream actuators. 11. Apparatus for controlling flow of a fluid material in an injection molding apparatus having a flow channel system having an upstream flow channel having a first axis through which fluid material is routed to a downstream channel having a second axis leading to an exit aperture to a mold cavity, the apparatus comprising: a first valve mechanism comprising an actuator drivably interconnected to a fluid material contacting member disposed within the upstream flow channel; the upstream channel communicating with and delivering fluid material to the downstream channel, the downstream channel delivering the fluid material to the exit aperture, the first and second axes of the upstream and downstream channels being non-coaxial; the fluid material contacting member having an outer surface portion engageable with a complementary surface of a portion of the upstream flow channel to stop flow of the fluid material, the actuator being controllably drivable to drive the outer surface portion of the fluid material contacting member through a selected range of gap distance relative to the complementary surface of the upstream flow channel; the fluid material having a rate of flow through the flow channel system that varies according to the gap distance. 12. The apparatus of claim 11 further comprising a controller interconnected to the actuator, the controller including an algorithm that controls movement of the actuator according to a variable defined by a signal received by the controller from a sensor that senses a selected condition of the fluid material flowing through the flow channel system. 13. The apparatus of claim 11 wherein the outer surface of the fluid contacting member engages with the complementary surface of the upstream channel upon upstream movement of the fluid contacting member. 14. The apparatus of claim 11 wherein the outer surface of the fluid contacting member engages with the complementary surface of the upstream channel upon downstream movement of the fluid contacting member. 15. The apparatus of claim 11 wherein the fluid contacting member comprises a pin having an axis slidably mounted for back and forth movement of the pin through the upstream channel; the pin having a bulbous protrusion along its axis, the bulbous protrusion having a smooth surface extending between an upstream end and a downstream end of the bulbous protrusion and a maximum diameter circumferential surface intermediate the upstream and downstream ends of the bulbous protrusion; the complementary surface of the upstream channel being complementary to the maximum diameter circumferential surface of the bulbous protrusion of the pin; the pin being slidable to a position within the channel such that the maximum diameter circumferential surface of the bulbous protrusion mates with the complementary interior surface portion of the channel. 16. The apparatus of claim 11 wherein the sensor is mounted for sensing the selected condition of the fluid material at a position upstream of the complementary surface of the upstream channel. 17. The apparatus of claim 11 wherein the sensor is mounted for sensing the selected condition of the fluid material at a position downstream of the complementary surface of the upstream channel. 18. The apparatus of claim 11 further comprising a second valve mechanism comprising a second actuator drivably interconnected to a second fluid material contacting member disposed within the downstream flow channel; the second fluid material contacting member having an outer surface portion engageable with a complementary surface of a portion of the downstream flow channel to stop flow of the fluid material; the second actuator being controllably drivable to drive the outer surface portion of the second fluid material contacting member between an open flow position and a closed flow position. 19. The apparatus of claim 18 wherein the second valve mechanism is interconnected to the flow controller, the algorithm including a set of instructions for controlling the drive of the second valve mechanism. 20. Apparatus for controlling flow of a fluid material in an injection molding apparatus having a flow channel system having an upstream flow channel having an axis through which fluid material is routed to a gate of a mold, the apparatus comprising: a first valve mechanism comprising a first actuator drivably interconnected to a fluid material contacting member disposed within the upstream flow channel; the upstream channel communicating with and delivering fluid material to, the gate of the mold; the axis of the upstream channel being offset from and not intersecting the gate of the mold; the fluid material contacting member having an outer surface portion engageable with a complementary surface of a portion of the upstream flow channel to stop flow of the fluid material, the actuator being controllably drivable to drive the outer surface portion of the fluid material contacting member through a selected range of gap distance relative to the complementary surface of the upstream flow channel; the fluid material having a rate of flow through the flow channel system that varies according to the gap distance. 21. The apparatus of claim 20 further comprising a downstream channel communicating with the upstream channel, the downstream channel having an axis intersecting the gate of the mold. 22. The apparatus of claim 20 wherein the gap distance is increased on movement of the flow contacting member in an upstream direction away from the complementary surface of the upstream flow channel. 23. The apparatus of claim 20 wherein the gap distance is increased on movement of the flow contacting member in a downstream direction away from the complementary surface of the upstream flow channel. 24. The apparatus of claim 20 wherein the fluid contacting member comprises a pin having an axis slidably mounted for back and forth movement of the pin through the upstream channel; the pin having a bulbous protrusion along its axis, the bulbous protrusion having a smooth surface extending between an upstream end and a downstream end of the bulbous protrusion and a maximum diameter circumferential surface intermediate the upstream and downstream ends of the bulbous protrusion; the complementary surface of the upstream channel being complementary to the maximum diameter circumferential surface of the bulbous protrusion of the pin; the pin being slidable to a position within the channel such that the maximum diameter circumferential surface of the bulbous protrusion mates with the complementary interior surface portion of the channel. 25. The apparatus of claim 20 further comprising a second valve mechanism comprising a second actuator drivably interconnected to a second fluid material contacting member disposed within the downstream flow channel; the second fluid material contacting member having an outer surface portion engageable with a complementary surface of a portion of the downstream flow channel to stop flow of the fluid material; the second actuator being controllably drivable to drive the outer surface portion of the second fluid material contacting member between an open flow position and a closed flow position. 26. The apparatus of claim 25 wherein the first and second valve mechanisms are interconnected to a flow controller having an algorithm that includes a set of instructions for controlling the drive of the first and second valve mechanisms.
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