A method for operating a measuring apparatus, comprising the steps as follows: ascertaining a flow velocity; comparing the ascertained flow velocity with a threshold value, which corresponds to a critical loading, especially to a resonant frequency, of a measuring apparatus immersion body protruding into the flow; and outputting a report, which signals reaching of a critical flow and/or frequency.

Embodiments of a portable verification system (5) can move from one in-field gas flow meter location to another and temporarily connect downstream of a main pipeline's meter run or station. A control valve (19) of the portable verification system (5) allows volume measurement at different flow velocities to be verified. In some embodiments, the portable verification system (5) is connected to the meter run (13) and the main pipeline by a corresponding slip or linearly adjustable pipeline section (30/70). This section (30/70) can extend horizontally and vertically, as well as swivel to provide versatility when connecting in the field. Adaptor fittings may be used to connect the system (5) to the meter run (13) and main pipeline or a quick connect/disconnect (105) may be used. Downtime is limited to the time required to complete a circuit between the meter run, portable verification system (5), and main pipeline.

A fluid flow analysis method and corresponding apparatus comprise performing two different sets of diagnostic checks which are associated with different types of flow meters, and cross-referencing the two sets of checks.

Methods, apparatuses and systems for providing offset calibration and fault monitoring are disclosed herein. An example controller component may comprise: a resistance-based bridge circuit; a signal conditioning circuit configured to condition an output of the resistance-based bridge circuit; a first diagnostic circuit coupled to the signal conditioning circuit configured to monitor an output of a first branch of the resistance-based bridge circuit; and a second diagnostic circuit coupled to the signal conditioning circuit configured to monitor an output of a second branch of the resistance-based bridge circuit.

An apparatus that is configured to test operation of a gas meter. The apparatus can include a process control member with operative circuitry that provides all functionality necessary to execute the test and to analyze the resulting data. This functionality includes data processing functions and a web server to allow communication between the apparatus and a remote device via a network. In one embodiment, the operative circuitry includes a first circuitry to regulate operation of a fluid moving unit that provides fluid to a meter-under-test. The operative circuitry can also include a second circuitry to collect data from one or more sensors disposed on the meter-under-test. The operative circuitry can also have a third circuitry to perform various operations necessary to calculate, in one example, a value for an operative characteristic that relates to the accuracy of the meter-under-test.

The measurement device comprises a transmitter for providing a transmitted signal at a frequency. The transmitter provides the transmitted signal to the transmitting antenna. A receiving antenna is arranged to receive the transmitted signal. A receiver is capable of receiving the transmitted signal from the receiving antenna. An electronic data processor is adapted to measure an observed parameter of the transmitted signal between the transmitting antenna and the receiving antenna to estimate the precise yield, where the observed parameter comprises observed attenuation, phase or both of the transmitted signal, as received at the receiver.

A method, meter and device capable of determining the accuracy, proof, or percent of error of a meter in service. The method is configured to establish one or more baseline flow measurements for the meter, the meter configured to measure a flow through the meter; obtain a current flow measurement for the meter; and determine a proving result in accordance with a comparing of the current flow measurement to the one or more baseline flow measurements.

An automated meter testing system that includes a fluid inlet valve fluidly coupled both to a fluid source and an inlet on the at least one meter. The fluid source provides fluid pressure to move fluid through the at least one meter. A flow control valve is fluidly coupled to the at least one meter opposite the fluid inlet valve. A valve controller that operates the flow control valve. A controller is electrically connected to the valve controller. The controller sends at least one signal to the valve controller to incrementally open or restrict the flow control valve to increase or decrease a flow rate of the fluid through the at least one meter.

A fluid flow analysis method and corresponding apparatus comprise performing two different sets of diagnostic checks which are associated with different types of flow meters, and cross-referencing the two sets of checks.

A flowmeter test system that tests a test target flowmeter by flowing fluid through the test target flowmeter and measuring the fluid having flowed through the test target flowmeter by a measurement part different from the test target flowmeter is disclosed. The flowmeter test system includes, a storage part to store the fluid, a distribution flow path to distribute the fluid between the storage part and the test target flowmeter, a measurement part introduction path to be connected to the distribution flow path and introduce the fluid into the measurement part, and a flow path switching part to switch between the distribution flow path and the measurement part introduction path. A pressure loss in a flow path from the flow path switching part to the storage part and a pressure loss in a flow path from the flow path switching part to the measurement part are same.