Systems and methods for sensing wear of reducing elements of a material reducing machine

What is claimed is: 1. A material reducing machine including wear sensing, the material reducing machine including: a rotatable reducing structure including a carrier and a plurality of reducing elements carried by the carrier; and a wear sensing system including a sensor that senses a general wear state of at least one of the reducing elements by sensing a general physical characteristic of the reducing element without measuring a position of a specific point on the rotatable reducing structure; wherein the sensor is an inductive sensor, and wherein the wear sensing system can sense the general physical characteristic of the reducing element when the material reducing machine is performing a reducing operation without contacting the reducing element. 2. The material reducing machine of claim 1 , wherein the rotatable reducing structure is at least partially covered by a shroud, wherein the sensor is mounted inside the shroud adjacent to the rotatable reducing structure, and wherein the material reducing machine further comprises a breaker structure positioned within the shroud upstream from the sensor, the breaker structure being spaced a first distance from a reducing boundary of the rotatable reducing structure and the sensor being spaced a second distance from the reducing boundary of the rotatable reducing structure, the second distance being longer than the first distance. 3. The material reducing machine of claim 2 , wherein the breaker structure includes first and second breaker bar structures, the first breaker bar structure being upstream from the second breaker bar structure. 4. The material reducing machine of claim 1 , wherein the wear sensing system includes a plurality of the sensors and a plurality of protective housings within which the sensors are mounted, wherein the wear sensing system includes a plurality of the rows of the protective housings that extend along the axis of rotation of the rotatable reducing structure, and wherein the sensors of adjacent rows are staggered. 5. The material reducing machine of claim 1 , wherein the sensor includes a plurality of inductive sensors, and wherein the inductive sensors are housed within trays with each tray having an open front face that does not cover a major face of its corresponding inductive sensor. 6. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing elements, and wherein the inductive sensors are arranged such that each of the reducing paths is assigned a corresponding one of the inductive sensors. 7. The material reducing machine of claim 6 , wherein the inductive sensors are arranged in a multi-row array. 8. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing elements, and wherein the inductive sensors each have an effective sensing distance, the inductive sensors also having a center-to-center spacing measured along the axis of rotation, the inductive sensors being arranged such that the center-to-center spacing is smaller than the effective sensing distance. 9. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing element, the inductive sensors including first and second inductive sensors having overlapping electromagnetic field boundaries, and the material reducing machine including a controller that operates the wear sensing system in a first sensing phase in which the first inductive sensor is energized and the second inductive sensor is de-energized, and that also operates the wear sensing system in a second sensing phase in which the first inductive sensor is de-energized and the second inductive sensor is energized. 10. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing element, the inductive sensors including first and second sets of inductive sensors, the inductive sensors of the first set having non-overlapping electromagnetic field boundaries and the sensors of the second set having non-overlapping electromagnetic field boundaries, the electromagnetic field boundaries of the first set overlapping the electromagnetic field boundaries of the second set, and the material reducing machine including a controller that operates the wear sensing system in a first sensing phase in which the first set of inductive sensors is energized and the second set of inductive sensors is de-energized, and that also operates the wear sensing system in a second sensing phase in which the first set of inductive sensors is de-energized and the second set of inductive sensors is energized. 11. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing element, and the material reducing machine includes a controller that operates the wear sensing system and processes base-line and real-time wear readings from the inductive sensors to determine the wear states of the reducing elements, wherein processing the base-line and real-time wear readings includes compensating for temperature variations. 12. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plurality of the sensors, wherein the sensors are inductive sensors, wherein the material reducing machine includes a shroud covering at least a portion of the rotatable reducing structure, wherein the inductive sensors are positioned within the shroud for sensing the reducing element, and the material reducing machine includes a controller that operates the wear sensing system and processes base-line and real-time wear readings from the inductive sensors to determine the wear states of the reducing elements, wherein processing the base-line and real-time wear readings includes compensating for variations in a rotational speed of the rotatable reducing structure. 13. The material reducing machine of claim 1 , wherein the reducing elements define a plurality of reducing paths, wherein the wear sensing system includes a plur