Abstract: A multi-axis vibration sensor with integral magnet optimizes sensor response in a non-permanently attachable package. In a preferred embodiment of the invention, the apparatus includes a housing having a magnet, a multi-axis vibration sensor for sensing vibration along multiple machine axes, and conditioning circuitry disposed within the housing. The magnet enables the apparatus to be placed in sensory contact with the machine. The vibration sensor senses machine vibration along multiple machine axes when the apparatus is in sensory contact with the machine, and the conditioning circuitry optimizes the frequency response of the vibration sensor by reducing the gain of the sensor output at resonance. The vibration sensor may be mounted directly to existing machine structure, such as the machine's outer casing. Two parallel feet facilitate stable mounting of the sensor curved surface. A keyed mounting pad may be employed to facilitate proper orientation of the sensor.

Abstract: An alignment system having an angular position sensing device using an accelerometer to determine the angular position of the device. Preferably, the angular position sensing device incorporates two dual-axis accelerometers oriented in a spaced apart relation for determining the angular position of a rotating body in space. The angular position sensing device is operable to account for centrifugal and angular acceleration errors due to the rotation of the rotating body in space, thereby providing an accurate angular position of the rotating body. The angular position sensor also determines the angular position of the rotating body based on a sensing axis having the greatest range of sensitivity according to the angular position of the rotating body.

Abstract: A rotating equipment monitoring device includes a set of sensors, such as temperature, speed, pressure, and vibration sensors, locally connected to a diagnostic unit having a plant communication interface and a processor that implements one or more diagnostic routines. The diagnostic unit collects data from the sensors and performs diagnostics thereon to detect actual or potential problems with the rotating equipment on a continuous or semi-continuous basis. Using the communication interface, the diagnostic unit automatically sends signals indicating detected conditions of the rotating equipment to a maintenance system or a control system via standard or common communication network, such as a HART or Fieldbus network. The diagnostic unit may also be intermittently coupled to an off-line computer, such a one associated with a service provider, who may verify or further define the diagnostics provided by the diagnostic unit.

Abstract: Information related to an operational condition of a machine in a process plant is generated, where the generated information is in a first data format. The information may be generated based on data in a second format. The second format may, for example, correspond to a format used by a certain type or types of process entities, whereas the first format may, for example, correspond to a format used to process operational condition information of other types of process entities in the process plant. Providing operational condition data for various types of process entities in a common format may, for example, assist an operator in ascertaining the relative importance of the operational condition for various types of entities.

Abstract: An apparatus for determining the rotational speed of an object returning diffuse reflections where no reflective singularity exists on the object or no clearly distinct light pulse is produced. A light source illuminates a target area on the object. An optical system receives the reflected light, selectively filters by wavelength, and focuses the light on a detector for signal processing. The reflected light signals may be a series of complex patterns that repeat once per revolution. A Fourier Transform with additional processing enhancements is performed on the signals and used as a basis to calculate the speed of the object The signal processing may be automated, resulting in a speed (RPM) solution being displayed for the operator of the device.

Abstract: An integral magnet vibration sensor apparatus optimizes sensor response in a non-permanently attachable package. In a preferred embodiment of the invention, the apparatus includes a housing having a magnet, a vibration sensor, and a conditioning circuit disposed within the housing. The magnet enables the apparatus to be magnetically attached to a machine. The vibration sensor senses machine vibration when the apparatus is attached to the machine, and the conditioning circuit optimizes the frequency response of the vibration sensor in a preferred embodiment by reducing the gain of the sensor output at resonance.

Abstract: An integrated lubricant analyzer apparatus. The apparatus includes a housing having a first fluid inlet port in flow communication with a chemical analysis device. A second fluid inlet port is included in the housing in flow communication with a particle analyzer. The housing also includes a third fluid inlet port in flow communication with an optical particle counting device. A syringe degassing port is attached to the housing for inverting and degassing a syringe containing a fluid sample for a particle count analysis before the fluid sample is injected into the third fluid inlet port. The apparatus includes a sample analysis sequencing procedure and a microprocessor for collection and manipulation of data from the chemical analysis device, the particle analyzer and the particle counting device. Features of the invention enable a trivector analysis of a fluid for maintaining machinery containing the fluid.

Abstract: A hand-held apparatus gathers and analyzes test data associated with rotating electric machines, where the test data is indicative of one or more operational characteristics of the mechanical equipment. The apparatus, which is operable to be carried by an operator from one machine to another along a test route, includes a sensor input port for receiving a sensor signal from a sensor, where the sensor signal is indicative of one or more operational characteristics of the rotating electric machines. The apparatus also includes a signal conditioning circuit for receiving the sensor signal, and for conditioning the sensor signal to produce a conditioned signal which is appropriate in format to be digitally processed. A processor, which is coupled to the signal conditioner, receives and processes the conditioned signal according to processing instructions and processing parameters to produce a test spectrum. The processing parameters determine one or more characteristics of the test spectrum.

Abstract: A method monitors an operational condition of an electric motor, and stores in a memory device general trend, prognostic, diagnostic, and hazardous event information indicative of the motor's operational condition. The method includes the steps of sensing characteristics indicative of the operational condition of the electric motor, such as vibration, temperature, magnetic flux, and the voltages applied to the motor's windings, and generating sensor signals related to the sensed characteristics. Upon the occurrence of a first circumstance, such when measurements of the motor's speed, winding temperature, and voltage, indicate that the motor is operating within its normal load profile, prognostic information is extracted from the sensor signals. The prognostic information provides a profile of the motor's operational condition over time without the influences of fluctuating loads, temperature, and voltage.

Abstract: A sensor mount provides for attachment of a vibration sensor or other sensor to a machine without having to turn or rotate the sensor. In conjunction with a sensor module having an integral sensor and a shoulder formed at the outer periphery of the sensor module, the invention provides a coupler having a lower threaded portion for being threadingly engaged with a corresponding threaded recess formed in the machine. An externally threaded upper portion of the coupler remains exposed above the machine structure. A fastener is configured to attach the sensor module to the coupler by engaging the sensor module shoulder and the exposed upper portion of the coupler. The fastener may be captured to the sensor module or separable therefrom. When attached to a machine, the fastener and coupler are substantially symmetrically positioned with respect to a central axis of the sensor.

Abstract: A sampling apparatus is described which contains a cylindrical member containing first and second annular recesses on opposing sides thereof and an opening therethrough. At least one resilient sealing member is disposed in each of the recesses. At least one foraminous support disposed in the cylindrical member over the opening adjacent the first recess. A porous medium is adjacent the foraminous support between the foraminous support and the sealing member. A compression housing is provided which contains first and second housing members for compressing the cylindrical member, sealing members, foraminous support and porous medium between the first and second housing members and a clamping means for compressing the sealing members to form a fluid tight seal. A fluid sample is fed by means of a fluid inlet in the first housing member which inlet is in flow communication with the opening, porous medium and foraminous support.

Abstract: A method for acquiring misalignment information as to centerlines of first and second in-line shafts utilizing a shaft alignment system including an analyzer having a memory. A sensor head mounted on the first shaft at an initial angular position relative to the centerline of the first shaft includes a microprocessor having memory, a collimated light source emitter for transmitting a collimated light beam in a first direction corresponding to the centerline of the first shaft, a detector having a detecting surface for detecting a collimated light source from a second direction corresponding to the centerline of the second shaft, and an angular position sensor for determining an angular position of the sensor head as the head is rotated about the centerline of the first shaft. The sensor head is rotated in a first or a second rotational direction relative to the centerline of the first shaft.

Abstract: A method of configuring and synchronizing a wireless machine monitoring system that has at least one chain, that includes at least one machine monitor and at least one repeater is disclosed. The wireless machine monitoring system may further include a master repeater that is in communication with the chain and a command station that is in communication with the master repeater. The wireless machine monitoring system is configured so that only one element of the system is communicating at any given time. In addition, bit error rate transmission tests are performed on the elements of the system to determine their ability to communicate at different transmission power levels. Thus, power consumption of battery powered elements is minimized by decreasing the amount of time the devices are active and by configuring the communicating elements to transmit at the lowest acceptable power level.

Abstract: A monitor attaches to a machine or proximate a machine to determine the health and operating status of the machine. The monitor is preferably self-contained, having its own internal power source, electronics, and sensor suite. One or more sensors are provided to sense machine operating characteristics such as temperature, flux, and vibration. Sensor outputs are processed and analyzed by monitor electronics to determine various operating parameters, including machine speed and load, and to determine when an anomalous machine operating condition is present. Monitor electronics are operable to transform time domain data generated by the sensors to frequency domain data for storage and/or analysis. A communications port enables a peripheral device, such as a notebook computer or portable data collector, to communicate with the monitor and download stored data.

Abstract: A portable digital ultrasonic monitoring system and method for use by an operator in detecting the ultrasonic waves and temperature variations produced by sources such as leaks in pipes, arcing, electrical corona and machinery defects is provided. The digital ultrasonic monitoring system includes a microprocessor based system in a hand held elongate housing that digitally analyzes and stores information received from its sensors. The digital ultrasonic monitoring system provides a referenced decibel output reading of the signal strength of the received ultrasonic signals. In addition, a heterodyned type audio signal that is related to the sensed ultrasonic signals is provided to the operator through a pair of headphones. The portable device has user input keys that allow the operator to select from a variety of different operating modes. A display displays a variety of different readings depending upon the operating mode of the device.

Abstract: A device detects an emission source of a vibration signal against a background of noise, where the vibration signal is produced by a mechanical system and has one or more frequency components. A sensor senses the vibration signal and produces a sensor signal corresponding to the vibration signal. The sensor has a mechanical frequency selection structure for mechanically resonating at desired frequencies and for mechanically attenuating a frequency component of the vibration signal having a frequency outside the desired frequencies. The mechanical frequency selection structure thus produces a mechanically-tuned sensor signal. Electrical frequency selection filters electrically attenuate a frequency component of the mechanically-tuned sensor signal having a frequency outside the desired frequencies. The electrical frequency selection filters thus produce an electrically-tuned sensor signal.

Abstract: An ultrasonic monitoring apparatus is provided for use by an operator in detecting ultrasonic vibrations and sound waves. The ultrasonic monitoring apparatus consists of a hand held device with a sensor socket that allows a variety of different types of sensors to be interchangeably installed in the hand held device. These sensors include both contact and airborne ultrasonic sensors as well as a combination temperature and ultrasonic sensor that allows the operator to simultaneously monitor the surface temperature of an object and the ultrasonic vibrations produced by the object. Identification information corresponding to the type of sensor is encoded on the individual sensors. The identification information is read by an identification circuit located in the hand held device. This identification information allows the hand held device to configure itself to operate with the type of sensor installed in the socket.

Abstract: An apparatus and method determines ultrasonic measurement parameters of ultrasonic measurements to be performed on a mechanical system, where the ultrasonic measurements are performed using a portable ultrasonic measurement device. The ultrasonic measurement parameters consist of information used in configuring the portable ultrasonic measurement device to make the ultrasonic measurements. The measurement parameters are used to configure an ultrasonic measurement device that uses an ultrasonic sensor to measure ultrasonic characteristics of the mechanical system, where the ultrasonic characteristics are indicative of an operating condition of the mechanical system. The apparatus includes a processor for generating user instruction messages that query a user concerning specific characteristics of the mechanical system on which the ultrasonic measurements are to be performed. The user instruction messages also provide response options from which the user chooses in responding to the instruction messages.

Abstract: A route based ultrasonic monitoring method for use by an operator in detecting when the ultrasonic sound produced by a device indicates the presence of a leak or machinery defect. The route based ultrasonic monitoring method uses a central processing location to store testing information concerning which machines to test and how to configure a portable ultrasonic sensing device to test them. At the appropriate time, the testing information is loaded from the central processing location into the portable processing and storage unit. The operator is then prompted by the portable processing and storage unit to proceed to a test location. Once at the test location, the portable processing and storage unit provides the testing information to the portable ultrasonic sensing device. The test is then performed by the operator with the portable ultrasonic sensing device and the test results are downloaded from the portable sensing device to the portable processing and storage unit.

Abstract: The invention provides a computerized method and apparatus which enables a user, even one who has little or no predictive maintenance skills, to establish a predictive maintenance database that defines information needed to monitor equipment in accordance with a predictive maintenance plan. The type of equipment components to be monitored and associated physical characteristics of the components are input to a computer as an equipment configuration, which may include one or more interconnected components. The computer includes a knowledge base that defines relationships between monitoring practices, component types, and physical characteristic information for component types. A predictive maintenance database is constructed for the components using the inference engine operating on the knowledge base, the selected component type, and the selected physical characteristic information. Multiple measurement technologies may be specified for each component.