Abstract: A method for operating a flow meter is provided. The flow meter includes a driver and pickoff sensors coupled to a flow tube. The driver is adapted to vibrate the flow tube in response to a drive signal. The method comprises setting a target pickoff voltage and measuring a flow meter temperature. The method further comprises generating a temperature compensated target pickoff voltage and controlling the drive signal to maintain a temperature compensated flow tube amplitude.

Abstract: A delta-sigma modulator (100) including a dithering capability for eliminating idle tones is provided according to the invention. The delta-sigma modulator (100) includes a bitstream converter (107) configured to generate a digital signal output substantially corresponding to an analog signal input, a periodicity detector (111) coupled to the bitstream converter (107) and configured to detect periodicity in the digital signal output, and a dithering sequence generator (116) connected to and activated by the periodicity detector (111). The dithering sequence generator (116) generates a dithering sequence. The delta-sigma modulator (100) further includes a pulse-width modulation (PWM) generator (119) coupled to the dithering sequence generator (116) and receiving the dithering sequence. The PWM generator (119) modulates the dithering sequence onto the analog signal input of the delta-sigma modulator (100) as a dithering signal.

Abstract: An instrument power controller (120) for adaptively providing an output voltage VO and an output current IO that together maintain a substantially constant electrical output power PO is provided. The controller (120) includes inputs (121) for receiving an input power PI, outputs (122) for providing the substantially constant output power PO to a variable impedance load L, and a communication path (126) for receiving a load voltage VL. The instrument power controller (120) is configured to determine an input voltage VI and an input current II, determine an effective resistance RL of the load L and set the output voltage VO and the output current IO based on the input voltage VI, the input current II, and the effective resistance RL. The output voltage VO is substantially independent from the input voltage VI. The output voltage VO and the output current IO are varied to maximize a load power PL while maintaining the substantially constant electrical output power PO.

Abstract: A very high frequency vibratory flow meter (100) is provided. The very high frequency vibratory flow meter (100) includes a flow meter assembly (10) including one or more flow conduits (103A, 103B). The flow meter assembly (10) is configured to generate a very high frequency response that is above a predetermined maximum decoupling frequency for the flow fluid independent of a foreign material size or a foreign material composition. The very high frequency vibratory flow meter (100) further includes meter electronics (20) coupled to the flow meter assembly (10) and configured to receive the very high frequency vibrational response and generate one or more flow measurements therefrom.

Abstract: A vibratory flow meter (5) for determining one or more flow fluid characteristics of a multi-phase flow fluid includes one or more flow conduits (103A,103B). The flow meter assembly (10) is configured to generate a very low frequency response that is below a predetermined minimum decoupling frequency for the flow fluid and to generate a very high frequency response that is above a predetermined maximum decoupling frequency for the flow fluid, independent of the foreign material size or the foreign material composition. The meter (100) further includes meter electronics (20) configured to receive one or more very low frequency vibrational responses and one or more very high frequency vibrational responses and determine the one or more flow fluid characteristics from the one or more very low frequency vibrational responses and the one or more very high frequency vibrational responses.

Abstract: A vibratory flow meter (5) for determining a derived fluid temperature Tf-derive of a flow material is provided according to the invention. The vibratory flow meter (5) includes a flow meter assembly (10) including one or more flow conduits (103), a meter temperature sensor (204) configured to measure a meter temperature Tm, an ambient temperature sensor (208) for measuring an ambient temperature Ta, and meter electronics (20) coupled to the meter temperature sensor (204) and to the ambient temperature sensor (208). The meter electronics (20) is configured to receive the meter temperature Tm and the ambient temperature Ta and determine the derived fluid temperature Tf-deriv of the flow material in the vibratory flow meter (5) using the meter temperature Tm and the ambient temperature Ta.

Abstract: A vibratory flow meter (5) for measuring flow characteristics of a three phase flow is provided according to the invention. The vibratory flow meter (5) includes a meter assembly (10) including pickoff sensors (105, 105?) and meter electronics (20) coupled to the pickoff sensors (105, 105?). The meter electronics (20) is configured to receive a vibrational response from the pickoff sensors (105, 105), generate a first density measurement of the three phase flow using a first frequency component of the vibrational response, and generate at least a second density measurement of the three phase flow using at least a second frequency component of the vibrational response. The at least second frequency component is a different frequency than the first frequency component. The meter electronics (20) is further configured to determine one or more flow characteristics from the first density measurement and the at least second density measurement.

Abstract: An adjustable mount assembly (100) is provided. The adjustable mount assembly (100) comprises a body (205) and an adjustment member (207) coupled to the body (205). The adjustment member (207) includes a threaded member (316) and a tension bar (210) coupled to the threaded member (316). The adjustable mount assembly (100) also includes one or more retaining member receivers (208A, 208B) formed in the body (205). One or more retaining members (206A, 206B) are provided with each of the one or more retaining members (206A, 206B) coupled to the tension bar (210) at a first end (206A?, 206B?) and adapted to engage the retaining member receiver (208A, 208B) at a second end (206A?, 206B?).

Abstract: A pneumatic actuator system (200) is provided according to the invention. The system (200) comprises a pneumatic actuator (100) including an actuator component (108), with the pneumatic actuator (100) being configured to include a first actuation phase and a second actuation phase. The system (200) further comprises one or more feedback sensors configured to provide one or more actuation feedback values, an actuator valve (213) coupled to and providing a first pneumatic pressure and a second pneumatic pressure to the pneumatic actuator (100), and a controller (240) coupled to the one or more feedback sensors and the actuator valve (213). The controller (240) is configured to receive the one or more actuation feedback values from the one or more feedback sensors and control the actuator valve (213) in order to actuate the actuator component (108) according to an actuation profile and according to the one or more actuation feedback values.

Abstract: A vibratory pipeline diagnostic system (100) is provided. The system (100) comprises at least one vibration generator (104) adapted to be affixed to a pipeline, at least one vibration sensor (107) adapted to be affixed to the pipeline, and a processing device (111) in communication with the at least one vibration generator (104) and the at least one vibration sensor (107). The processing device (111) is configured to vibrate a portion of the pipeline using the at least one vibration generator (104), receive a vibrational response to the vibration from the at least one vibration sensor (107), compare the vibrational response to one or more previous vibrational responses of the pipeline, and indicate a fault condition if the vibrational response differs from the one or more previous vibrational responses by more than a predetermined tolerance.

Abstract: A vibratory flow meter (100) for correcting for entrained gas in a flow material is provided. The vibratory flow meter (100) comprises a flow meter assembly (10) configured to generate a vibrational response for the flow material, a bubble size sensor (50) configured to generate a bubble measurement signal for the flow material, and meter electronics (20) coupled to the flow meter assembly (10) and to the bubble size sensor (50). The meter electronics (20) is configured to receive the vibrational response and the bubble measurement signal, determine a bubble size of bubbles in the flow material using at least the bubble measurement signal, determine one or more flow characteristics of the flow material using at least the vibrational response and the bubble size.

Abstract: A control valve (100,200) with a two-piece shifting mechanism is provided. The special control valve has two levers, one is a sealing lever (106,206) and the other is a shifting lever (104,204). The sealing lever (106,206) has a channel (116,216) on one of its ends to couple together different ports (SP, S, P, IS) to change the airflow direction. Each lever has its own axis. The shifting lever and the sealing lever interact through an oval opening (114) and a cylindrical boss (112), obtaining two angular range motions. When a small angular input is put on the shifting lever it will produce a large angular output at the second end of the sealing lever. It will achieve a multiple-position switching.

Abstract: A partially bonded brace bar assembly is provided according to an embodiment of the invention. A vibrating element adapted to vibrate about a bending axis (W, W?) is provided. The vibrating element has a high stress region (412). A brace bar (201 204) is bonded to the vibrating element using a partial bond (420). The partial bond (420) is formed only in the high stress region (412).

Abstract: Meter electronics (20) for a flow meter (5) is provided according to an embodiment of the invention. The meter electronics (20) includes an interface (201) for receiving a vibrational response from the flow meter (5) and a processing system (203) in communication with the interface (201). The vibrational response is a response to a vibration of the flow meter (5) at a substantially resonant frequency. The processing system (203) is configured to receive the vibrational response from the interface (201), determine a frequency (?0) of the vibrational response, determine a response voltage (V) and a drive current (I) of the vibrational response, measure a decay characteristic (?) of the flow meter (5), and determine the stiffness parameter (K) from the frequency (?0), the response voltage (V), the drive current (I), and the decay characteristic (?).

Abstract: A locking piston assembly (100) is provided according to the invention. The locking piston assembly (100) includes a piston chamber (107), a piston rod (106) configured to be substantially extended from and substantially retracted into the piston chamber (107), and a piston head (108) coupled to the piston rod (106) and configured to move reciprocally in the piston chamber (107). The locking piston assembly (100) further includes at least one lock (120) configured to mechanically lock the piston head (108) and the piston rod (106) in at least a substantially fully extended position. The lock (120) is configured to unlock the piston head (108) and the piston rod (106) in a presence of a pressurized fluid provided to retract the piston rod ( 106). The pressurized fluid is introduced into the piston chamber (107) and the piston rod (106) is retracted only after the lock (120) is unlocked.

Abstract: A pneumatic actuator (100) is provided according to the invention. The actuator (100) comprises an actuator body (102) and a piston rod (108) extending from the actuator body (102). The piston rod (108) moves over an actuation span. The actuation span comprises a first stroke span that is traversed by the piston rod (108) at a first actuation speed and a second stroke span that is traversed at a second actuation speed that is substantially slower than the first actuation speed.

Abstract: A meter electronics (20) for generating a drive signal for a vibratory flowmeter (5) is provided according to an embodiment of the invention. The meter electronics includes an interface (201) and a processing system (203). The processing system is configured to receive the sensor signal (201) through the interface, phase-shift the sensor signal (210) substantially 90 degrees to create a phase-shifted sensor signal, determine a phase shift value from a frequency response of the vibratory flowmeter, and combine the phase shift value with the sensor signal (201) and the phase-shifted sensor signal in order to generate a drive signal phase (213). The processing system is further configured to determine a sensor signal amplitude (214) from the sensor signal (210) and the phase-shifted sensor signal, and generate a drive signal amplitude (215) based on the sensor signal amplitude (214), wherein the drive signal phase (213) is substantially identical to a sensor signal phase (212).

Abstract: A fluid control device is disclosed that is configured to vent pilot volume through an exhaust port or exhaust passageway (140) integrated into the fluid control device. The fluid control device has a fluidic switch (112) configured to switch a pilot volume into the exhaust port or exhaust passageway (140) when a signal port or signal passageway (114) is de-pressurized. The fluidic switch (112) couples the signal port or signal passageway (114) to the pilot volume when the signal port or signal passageway (114) is pressurized.

Abstract: The displacement sensor (100) includes a rod (103) including a conical convex graduated magnetically anomalous region (105) and a magnetic sensor (110) located in close proximity to the concical convex graduated magnetically anomalous region (105). The magnetic sensor (110) generates a positional signal that is related to the position of the concical convex graduated magnetically anomalous region (105) in relation to the magnetic sensor (110).