Abstract: A method and apparatus is disclosed that guides a user through a sequence of steps that will allow the user to complete a predefined task using the flow meter. The steps include: selecting a predefined task, displaying a sequence of steps that directs the user through a process for using the Coriolis flow meter to complete the predefined task, and operating the Coriolis flow meter in response to the sequence of steps to complete the predefined task.

Abstract: Meter electronics for geometric thermal compensation in a flow meter is provided according to the invention. The meter electronics includes an interface configured to receive sensor signals and a temperature signal (T) of the flow meter. The meter electronics further includes a processing system coupled with the interface and configured to receive the sensor signals and the temperature signal (T) and compute a geometric thermal compensation factor (TFe) for one or more flow conduits of the flow meter using the temperature signal (T). The geometric thermal compensation factor (TFe) is used to process the first and second sensor signals.

Abstract: A selection system (100) that selects fluid process systems is comprised of an interface (101, 103) and a processing system (102). The processing system (102) directs the interface (101, 103) to transfer a first signal that indicates user prompts. The interface (101, 103) receives a second signal that indicates user inputs provided responsive to the user prompts. The user inputs indicate fluid process information. The processing system (102) processes the fluid process information to select a first one of the fluid process systems. The processing system (102) obtains first performance and specification information for the first one of the fluid process systems. The processing system (102) directs the interface (101, 103) to transfer a third signal that indicates the first performance and specification information for the first one of the fluid process systems.

Abstract: A restraint system (14) for a seat belt (22) is provided according to an embodiment of the invention. The restraint system (14) comprises one or more pneumatic ports (42, 44) for actuating the restraint system (14) from a first position to a second position. The restraint system (14) also comprises one or more pyrotechnic ports (52, 54) for actuating the restraint system (14) from either the first position or the second position to a third position.

Abstract: The present invention relates to a vibrating flow device that includes at least one conduit, at least one drive, at least one pick-off, and at least one housing. The at least one drive vibrates the at least one conduit at one or more drive frequencies and the at least one pick-off measures the motion of the at least one conduit. The at least one housing encompasses at least a portion of the at least one conduit. The at least one housing's modes of vibration occur at frequencies that exceed the one or more drive frequencies.

Abstract: A system and method for operating a solenoid valve is disclosed. The solenoid valve is operated by moving a first valve element (4) with respect to a second valve element (6, 7) a first distance. And then pulling the second valve element (6, 7) with the first valve element (4) a second distance where the second valve element (6, 7) moves against resistance from a seal (8) and where the movement of the second valve element (6, 7) opens a gap with respect to an orifice (10). The second element (6, 7) then moves a third distance under spring load to open an increased gap with respect to the orifice (10).

Abstract: A flow meter (200) includes a flow tube (210) and a balance system (211). The balance system (211) is coupled to the flow tube (210). Both the flow tube (210) and the balance system (211) have a center of mass. The balance system (211) is sized and located such that the combined center of mass (Ccm) of the flow tube (210) and the balance system (211) lies proximate an axis of rotation of the flow tube (210).

Abstract: A blow molding machine having the valves integrated into the valve block is disclosed. The valve pistons form annular rings stacked vertically along the stretch rod axis. The valve pistons activate by moving up/down along the stretch rod axis. The valve seat for each vertically stacked valve is formed radially around the stretch rod.

Abstract: A radiometer is provided. The radiometer includes a sensor and a radiation transparent dome. The radiation transparent dome surrounds the sensor. The radiometer also includes one or more fluid nozzles. The one or more fluid nozzles are adapted to apply a fluid on the radiation transparent dome in order to clean the surface of the radiation transparent dome.

Abstract: A pressure switch (100) having a housing (101) and a connector (106) coupled to the housing (101) is provided. The housing (101) comprises a first chamber (212) and a second chamber (213). The first and second chambers (212, 213) are separated by an integrated diaphragm (102). The integrated diaphragm (102) has a first side (210) and a second side (211). The integrated diaphragm (102) flexes in response to a pre-determined pressure acting on the second side (211). A first bushing (103) is inserted into the first chamber (212) of the housing (101) and coupled to the first side of the integrated diaphragm (102). The connector (106) comprises one or more electrical contact members (219) and at least one switch (105), the at least one switch (105) communicates with the first side (210) of the integrated diaphragm (102).

Abstract: Meter electronics (20) for processing sensor signals in a flow meter is provided according to an embodiment of the invention. The meter electronics (20) includes an interface (201) for receiving a first sensor signal and a second sensor signal and a processing system (203) in communication with the interface (201) and configured to receive the first sensor signal and the second sensor signal, generate a ninety degree phase shift from the first sensor signal, and compute a frequency from the first sensor signal and the ninety degree phase shift. The processing system (203) is further configured to generate sine and cosine signals using the frequency, and quadrature demodulate the first sensor signal and the second sensor signal using the sine and cosine signals in order to determine the phase difference.

Abstract: A cartridge (10) for dispensing a reagent contained in a reagent reservoir (32). The reservoir (32) is in fluid communication with a deformable dispense tube (26) that is a least partially compressible, in use, to dispense a volume of reagent from the tube (26). The reservoir (32) defines an enclosed gas space (46) above the reagent, and the cartridge (10) includes a gas vent (40) that, in use, admits gas to the gas space (46) in response to dispense of reagent from the tube (26) that serves to control the reservoir pressure as the reservoir (32) is depleted by subsequent dispensing of reagent. A dispenser employing the cartridge (10) and a method of dispensing a volume of reagent are also disclosed.

Abstract: A rocker type diaphragm valve is disclosed. The diaphragm (428) in the diaphragm valve is asymmetric and the stroke of the diaphragm is offset from the center of the diaphragm. The two sealing surfaces (318, 320) that the diaphragm acts against form two planes that make an angle with respect to ones another. The diaphragm (428) may be fabricated in only one piece. The diaphragm (428) may also be made from a resilient material and shaped in such a way as to create a spring force holding the diaphragm into a default position in the valve.

Abstract: A modular coupling system comprises a connector (200, 201) having a generally cylindrical center section (224) with a bore (208) extending from a front face (206) of the connector (200, 201) through to a back side of the connector. The connector (200, 201) has a first (220) and a second wing (222) extending from the generally cylindrical center section (224) of the connector (200, 201). A first flange (202) extends from a front side of the first wing towards a top side of the connector (200, 201), and a second flange (204) extends from a back side of the first wing towards a bottom side of the connector (200, 201). A third flange (202) extends from a front side of the second wing towards the bottom side of the connector (200, 201), and a second flange (204) extends from a back side of the first wing towards the top side of the connector (200, 201).

Abstract: A method for detecting a cable fault in a cabling of a flow meter is provided according to an embodiment of the invention. The method includes testing one or more first pickoff wires and one or more second pickoff wires of the cabling for pickoff open wire faults. The method further includes testing the first pickoff wires and the second pickoff wires for pickoff connection orientation faults if no pickoff open wire faults are determined in the first pickoff wires and the second pickoff wires. The method further includes testing one or more driver wires of the cabling for driver open wire faults. The method further includes testing the driver wires for a driver connection orientation fault if no driver open wire faults are determined in the driver wires.

Abstract: A portable heater (100) is provided. The portable heater (100) comprises an air inlet (108) and an air outlet (118). The portable heater (100) also comprises a heating chamber (115) including one or more heating elements (230). A preheating chamber (114) is provided that is located between the air inlet (108) and a heating chamber inlet (116).

Abstract: A dual-driver vibratory flowmeter (100) is provided according to the invention. The dual-driver vibratory flowmeter (100) includes a first flowtube (102A) and a second flowtube (102B) positioned substantially adjacent to the first flowtube (102A). The first and second flowtubes (102A, 102B) include a longitudinal length L. The dual-driver vibratory flowmeter (100) further includes a first driver (121) comprising first and second driver portions (121A, 121B) and affixed to the first and second flowtubes (102A, 102B), with the first driver (121) being located at a third longitudinal location Y along the first and second flowtubes (102A, 102B) and a second driver (122) comprising first and second driver portions (122A, 122B) and affixed to the first and second flowtubes (102A, 102B), with the second driver (122) being located substantially at the third longitudinal location Y and substantially spaced-apart from the first driver (121).

Abstract: A valve is provided according to one embodiment of the invention. The valve comprises a piston (104), a housing (106) surrounding the piston (104), an inlet (108) capable of allowing fluid into the valve, an exhaust (110) capable of allowing fluid out of the valve, a light source (112) capable of emitting light directed at the piston (104), and a light sensor (114) capable of measuring an intensity of the light received from the light source (112), said intensity varying based on the position of the piston (104) within the housing (106). A piston assembly is also provided according to an embodiment of the invention, in which a light source 608 and a light sensor 610 may be used to determine the position of the piston. A system is provided for obtaining and analyzing operational status information is provided according to an embodiment of the invention. An action may be automatically taken depending on the analyzed operational status.

Abstract: The present invention relates to a leveling valve including a first port, a second port, a third port, a valve, and a clutch. The clutch is provided with an engaged position and a disengaged position. At least a portion of the clutch may move relative to the valve when the clutch is in the disengaged position. The clutch moves the valve when the clutch is in the engaged position. The valve is movable between a first position, a second position, and a third position. When the valve is in the first position, the valve blocks a first pathway, which extends from the first port, from connecting with a second pathway, which extends from the second port. When the valve is in the second position, the valve allows the first pathway to connect with the second pathway. When the valve is in the third position, the valve allows the second pathway to connect with a third pathway, which extends from the third port.

Abstract: A fluid delivery system includes a flow control device and a Coriolis mass flowmeter in fluid communication with the flow control device. The Coriolis flowmeter has a flow-tube made of a high-purity plastic material, such as PFA, making the delivery system suitable for high purity applications. A controller provides a control output signal to the flow control device, which may comprise a pinch valve, so as to vary the flow control device output in response to a setpoint signal and measurement signals received from the flowmeter.