A wiping assembly for a fluid ejection device includes a sled slidably movable relative to the fluid ejection device. The wiping assembly further includes a length of wiping material. An indicator slidably coupled to the wiping assembly is included. The indicator changes position relative to the wiping assembly and restricts movement of the wiping assembly to an initial position to indicate a level of usage of the wiping material.

The invention relates to a field device for automation engineering having a housing, wherein the housing has at least one associated pushbutton switch. Operation of the pushbutton switch is detected, according to the invention, inside the housing without the presence of mechanical or electrical passageway through the wall of the housing. For this, the housing does not need to have a blind hole or an inwardly directed depression. This is achieved by a rigid arrangement of a first element for producing a magnetic field on the outer wall of the housing. By means of interaction with a second element for influencing the magnetic field of the first element, which is arranged in an operating element, a variable magnetic field is produced inside the housing. This magnetic field is sensed by a sensor. On the basis of the alteration in the magnetic field, the sensor can determine whether the pushbutton switch is currently being operated.

A control sensor assembly for an agricultural harvester is provided. The control sensor assembly includes a linkage for connection to a header height control system, a bushing, a mount and a sensor mounted to the mount. The bushing includes a first end connected to the linkage and a second end housing a magnet. The mount includes a body having a through hole extending from a first surface to a second surface opposite the first surface for receiving the bushing and a first rotational stop about the first surface and adjacent the through hole. The sensor is spaced from the second end of the bushing. The control sensor assembly according to the subject application is designed to provide an improved mount for the control sensor assembly that utilizes a single mount to perform multiple functions.

A target detection assembly includes a detection member adapted to generate a first input signal, and an emulator module is removably secured to the detection member. The emulator module includes an emulator housing assembly removably secured to the detection member and a selection portion is disposed on the emulator housing assembly. The selection portion is configured to be oriented in a first and second selection mode. In the first selection mode, a first emulation circuit disposed within the emulator housing assembly receives the first input signal, processes the first input signal, and outputs a first output signal that is different than the first input signal. In the second selection mode, a second emulation circuit disposed within the emulator housing assembly receives the first input signal, processes the first input signal, and outputs a second output signal that is different than the first input signal and the first output signal.

Disclosed are systems, methods and apparatuses for detecting tampering with a utility meter. A method may comprise measuring a magnetic field created by a rotating magnet in the meter by a removal detector sensor in a solid-state register (SSR). In addition, the SSR may be configured to detect when the SSR is dislodged or removed from the utility meter. The sensor may comprise a register removal tamper alert. The tamper detection methods described herein provide improved techniques for preventing and deterring attempts to alter meters and steal utility-provided resources.

A multi-turn non-contact sensor includes a rotationally mounted driver magnet, and a rotationally mounted driven magnet. The driver magnet has a first number (P.sub.1) of magnetic poles and is configured to selectively receive a rotational drive torque and, upon receipt of the drive torque, to rotate about a first rotational axis. The driven magnet is spaced apart from, and is coupled to receive a magnetic force from, the driver magnet. The driven magnet has a second number (P.sub.2) of magnetic poles and is responsive to rotation of the driver magnet to rotate about a second rotational axis that is parallel to the first rotational axis. The driven magnet rotates one complete revolution each time the driver magnet rotates a predetermined number (N) of complete revolutions, P.sub.2>P.sub.1, and N=(P.sub.2/P.sub.1).