초록 ▼

A gate control system that provides repeatable and reliable gate position sensing in a fully open position, a fully closed position, or both. In various embodiments, proximity sensors are maintained in biased contact (continuously or intermittently) with the gate panel throughout the travel range of

A gate control system that provides repeatable and reliable gate position sensing in a fully open position, a fully closed position, or both. In various embodiments, proximity sensors are maintained in biased contact (continuously or intermittently) with the gate panel throughout the travel range of the gate panel. The system may also include anti-fouling or “self-cleaning” of the proximity sensor(s), whereby the proximity sensors are cleared of materials that would otherwise interfere with the repeatability of the position sensing.

대표청구항 ▼

1. A gate assembly, comprising: a gate frame that defines an opening, the opening being adapted for flow of a bulk material therethrough;a gate panel translatably mounted within the gate frame, the gate panel including a first edge that is translatable within the opening of the gate frame during ope

1. A gate assembly, comprising: a gate frame that defines an opening, the opening being adapted for flow of a bulk material therethrough;a gate panel translatably mounted within the gate frame, the gate panel including a first edge that is translatable within the opening of the gate frame during operation, anda second edge opposite the first edge; anda closed position proximity sensor assembly positioned to detect the second edge of the gate panel when the gate panel is in a fully closed position,wherein the closed position proximity sensor assembly is biased against the gate panel to maintain sliding contact with the gate panel over an entire range of travel of the gate panel. 2. The gate assembly of claim 1, comprising: an open position proximity sensor assembly positioned to detect the second edge of the gate panel when the gate panel is in a fully opened position,wherein the open position proximity sensor assembly is biased against the gate panel and is in sliding contact with the gate panel when the gate panel approaches the fully opened position. 3. The gate assembly of claim 2, wherein one or both of the closed position proximity sensor assembly and the open position proximity sensor assembly includes an inductive sensor. 4. The gate assembly of claim 2, wherein the open position proximity sensor assembly is disengaged from the gate panel when the gate panel is in the fully closed position. 5. The gate assembly of claim 4, wherein a contact face of the open position proximity sensor assembly is arranged at an acute angle relative to a plane of travel of the gate panel when disengaged from the gate panel, the open position proximity sensor being configured to engage and be biased against the gate panel after engagement with the gate panel. 6. The gate assembly of claim 5, wherein the contact face rotates into an orientation that is substantially parallel to the plane of travel after engagement with the gate panel. 7. The gate assembly of claim 5, wherein the contact face of the open position proximity sensor is positioned to intersect the plane of travel. 8. The gate assembly of claim 2, wherein one or both of the closed position proximity sensor assembly and the open position proximity sensor assembly includes a sensing element disposed in a housing. 9. The gate assembly of claim 8, wherein the sensing element of the one or both of the closed position proximity sensor assembly and the open position proximity sensor assembly includes a sensing face that is substantially flush with a contact face of the housing, the contact face of the housing being configured for the sliding contact with the gate panel. 10. The gate assembly of claim 8, wherein one or both of the closed position proximity sensor assembly and the open position proximity sensor assembly is biased against the gate panel by a spring that is in contact with the housing. 11. The gate assembly of claim 10, wherein one or both of the closed position proximity sensor assembly and the open position proximity sensor assembly is mounted to a bracket, the spring acting to bias the housing away from the bracket. 12. The gate assembly of claim 2, wherein the open position proximity sensor assembly includes: a bracket;a sensing element disposed in a housing, the housing being pivotally coupled to the bracket; anda spring disposed between and in contact with the housing and the bracket,wherein the open position proximity sensor assembly is biased against the gate panel by the spring. 13. The gate assembly of claim 1, wherein the gate panel is adapted for translation to a plurality of intermediate static positions, each of the plurality of intermediate static positions being intermediate between the fully closed position and the fully open position within the gate frame. 14. The gate assembly of claim 1, wherein: the gate frame includes a retraction bay adjacent the opening; andthe second edge of the gate frame is translatable within the retraction bay of the gate frame during operation. 15. A gate assembly, comprising: a gate frame that defines an opening, the opening being adapted for flow of a granular agricultural material therethrough;a gate panel translatably mounted within the gate frame, the gate panel including a first edge that is translatable within the opening of the gate frame during operation, anda second edge opposite the first edge; andan open position proximity sensor assembly positioned to detect the second edge of the gate panel when the gate panel is in a fully opened position,wherein the open position proximity sensor assembly is biased against the gate panel and is in sliding contact with the gate panel when the gate panel approaches the fully opened position. 16. The gate assembly of claim 15, comprising: a closed position proximity sensor assembly positioned to detect the second edge of the gate panel when the gate panel is in a fully closed position,wherein the closed position proximity sensor assembly is biased against the gate panel to maintain sliding contact with the gate panel over an entire range of travel of the gate panel. 17. The gate assembly of claim 15, wherein a contact face of the open position proximity sensor assembly is arranged at an acute angle relative to a plane of travel of the gate panel when disengaged from the gate panel, the open position proximity sensor being configured to engage and be biased against the gate panel after engagement with the gate panel. 18. The gate assembly of claim 17, wherein the contact face of the open position proximity sensor is positioned to intersect the plane of travel. 19. The gate assembly of claim 15, wherein the open position proximity sensor assembly includes: a bracket;a sensing element disposed in a housing, the housing being pivotally coupled to the bracket; anda spring disposed between and in contact with the housing and the bracket,wherein the open position proximity sensor assembly is biased against the gate panel by the spring. 20. The gate assembly of claim 19, wherein the housing is pivotable about a pivot pin that extends lateral to a direction of travel of the gate panel. 21. The gate assembly of claim 19, wherein the housing is pivotable about a head of a mounting fastener, the mounting fastener extending from the bracket to the housing, the head of the mounting fastener being in contact with the bracket. 22. The gate assembly of claim 19, wherein the spring is a coil spring.