Abstract: A micro-position gap sensor assembly, including a structural housing, a flexible diaphragm fixedly attached at a first end of the structural housing, and a shaft orthogonally attached to the flexible diaphragm. The micro-position gap sensor assembly may further include a first retainer coupled to the shaft, a second retainer formed as a step of the structural housing, and a plate gap sensor. The plate gap sensor may include a non-contact sensor plate biased by a compression spring so that the non-contact sensor plate is held against a portion of the second retainer. The plate gap sensor may further include a target plate positioned adjacent the non-contact sensor plate and separated therefrom by a gap. The target plate may be biased by a return spring so that the target plate is held against a portion of the first retainer. The target plate may be coupled to the shaft.

Abstract: A micro-position gap sensor assembly, including a structural housing, a flexible diaphragm fixedly attached at a first end of the structural housing, and a shaft orthogonally attached to the flexible diaphragm. The micro-position gap sensor assembly may further include a first retainer coupled to the shaft, a second retainer formed as a step of the structural housing, and a plate gap sensor. The plate gap sensor may include a non-contact sensor plate biased by a compression spring so that the non-contact sensor plate is held against a portion of the second retainer. The plate gap sensor may further include a target plate positioned adjacent the non-contact sensor plate and separated therefrom by a gap. The target plate may be biased by a return spring so that the target plate is held against a portion of the first retainer. The target plate may be coupled to the shaft.

Abstract: A micro-position gap sensor assembly including a structural housing and a flexible diaphragm fixedly attached forming a barrier against fluid ingress. The structural housing includes a shaft orthogonally attached to the flexible diaphragm, a first retainer including one or more standoffs, a second retainer, and a parallel plate gap sensor. The parallel gap plate sensor includes a non-contact sensor plate biased against a portion of the first retainer defining a plane of the non-contact sensor plate and receiving a biasing force in opposition of the first retainer from the second retainer, a target plate comprised of a conductive paramagnetic material. The parallel plate gap sensor is configured such that displacement of one of the target plate or the non-contact sensor plate changes a distance between the target plate and the non-contact sensor plate.

Abstract: A micro-position gap sensor assembly including a structural housing and a flexible diaphragm fixedly attached forming a barrier against fluid ingress. The structural housing includes a shaft orthogonally attached to the flexible diaphragm, a first retainer including one or more standoffs, a second retainer, and a parallel plate gap sensor. The parallel gap plate sensor includes a non-contact sensor plate biased against a portion of the first retainer defining a plane of the non-contact sensor plate and receiving a biasing force in opposition of the first retainer from the second retainer, a target plate comprised of a conductive paramagnetic material. The parallel plate gap sensor is configured such that displacement of one of the target plate or the non-contact sensor plate changes a distance between the target plate and the non-contact sensor plate.