Some embodiments of the disclosure provide a Coriolis mass flowmeter with a non-circular section. In some examples, the mass flow meter includes a flow inlet device and a flow outlet device. The flow inlet device and the outlet device each include a flange connecting disc, a flange sealing disc, a connector, and a flow tube. The flange sealing disc is attached to the outer surface of the flange connecting disc. The connector is connected to the flange connecting disc. A body of the flow tube is located in the connector, and an outlet of the flow tube is connected to the flange sealing disc. The cross section of a measurement body of the flow tube is a circular cross section, and the cross section of the outlet of the flow tube is a non-circular cross section.

Systems embodiments of the disclosure provide a Coriolis mass flowmeter with a built-in supporting structure. In some examples, the Coriolis mass flowmeter includes a first flow divider, a second flow divider, a support tube, a first case, a second case, and a flow tube. One end of the flow tube is connected to the first flow divider, and another end of the flow tube is connected to the second flow divider. The first flow divider and the second flow divider are fixed by the support tube, the first case is connected to the first flow divider and the second flow divider, the second case is connected to the first flow divider and the second flow divider, the first case is connected to the second case, and the first case and the second case are wrapped around the support tube and the flow tube.

In some embodiments, the disclosure provide a Coriolis flowmeter with multiple flow tubes, including a flow sensor and a flow transmitter is provided. The flow sensor includes a sensor housing, a sleeve, and two symmetrical flanges. A sensor assembly is arranged in the sensor housing, and the sensor assembly includes at least two flow tube groups, each flow tube group includes at least two flow tubes. Two flow tubes with the same size and geometry in different groups form a flow tube pair. At least two flow tube pairs are provided by at least two flow tube groups, each flow tube pair is fixedly connected together by at least one pair of node plates, a measurement area of the flow tubes is between an innermost pair of node plates, and each flow tube group is connected to a driver and a detector.

An embodiment of a balance bar (230) is disclosed. The balance bar (230) comprises a first side portion (231) having a hollow interior for receiving a flow tube (220), a central portion (233) having a hollow interior for receiving a flow tube (220), and a first side flexible portion (234) comprising at least one flexible coupler (250), the first side flexible portion (234) coupling the first side portion (231) with the central portion (233), wherein the first side portion (231) and the central portion (233) are both more rigid than the first side flexible portion (234).

The present disclosure relates to a Coriolis measuring transmitter of a Coriolis measuring device for measuring a mass flow or a density of a medium flowing through a pipe, which includes: at least one pair of measuring tubes arranged to oscillate relative to each other, wherein each measuring tube includes a centrally arranged bend, at least one driver and at least two vibration sensors; two guiding devices, each including a fluid chamber with a first opening for connection with the pipe and second openings for each measuring tube for connection with the measuring tubes, wherein the guiding devices are each formed from multiple parts, for example, formed from two parts, wherein a first part forms a pipe connecting part, and wherein at least one second part forms a measuring tube connecting part.

A transducer assembly 200 for a vibrating meter 5 having meter electronics 20 is provided according to an embodiment. The transducer assembly 200 comprises a coil portion 204A comprising a coil bobbin 220 and a coil 222 wound around the coil bobbin 220. A magnet portion 204B comprises a magnet. The coil portion 204A and the magnet portion 204B are constrained in both the x and y axis of travel, such that the coil portion 204A is prevented from colliding with the magnet portion 204B.

A method for forming a pressure fit hermetic seal between a second component (104) and an interior member (108) is disclosed. The method comprises steps of coupling the second component (104) to a first component (102) by applying heat to one or more of the first component (102) and the second component (104) and allowing the first component (102) and the second component (104) to cool, wherein the applying heat step and allowing to cool step form the hermetic seal by causing compression of a hermetic element (106) against the second component (104) and by causing compression of the hermetic element (106) against the interior member (108).

A vibrating-tube fluid measurement device includes an electrical isolator formed of glass, wherein the vibrating tube is mounted to a base block via the electrical isolator and electrically isolated from the base block via the electrical isolator.

An integrated flow meter includes a support and one or more flow sensitive member(s) integrated with the support. The support is formed by using an injection molding process that overmolds material over an outer surface of the flow sensitive member(s). The materials for the support and for the flow sensitive member(s) preferably are polymeric materials.

A system and method for monitoring drilling operations by dividing a flow of fluid into at least one discrete fluid unit, circulating the fluid unit through a wellbore, and comparing a measured change to a property of the fluid unit to a predicted change in the property of the fluid unit. In addition to measuring the change to the property of the fluid unit, the fluid unit may be tracked by iteratively calculating the location of the fluid unit as it passes through the wellbore. Data collected for the fluid unit by a control system may be analyzed and used by the control system or an operator to diagnose problems or improve overall efficiency of drilling operations.