A vortex flowmeter for measuring a flow rate of a fluid has a flowtube and a bluff body positioned in the flowtube for shedding vortices in the fluid when the fluid flows through the flowtube. A sensor is positioned to detect the vortices. A cleaning port is positioned to allow a stream of fluid to be directed into the flowtube through the cleaning port toward the sensor for cleaning material away from the sensor. A method of cleaning the vortex flowmeter includes injecting a fluid into the vortex flowmeter toward the sensor through the cleaning port.

A vortex meter for measuring a flow rate of a fluid has a flowtube and a bluff body positioned in the flowtube for shedding vortices in the fluid when the fluid flows through the flowtube. The vortex meter has a sensor positioned to detect the vortices. The bluff body has a forward-facing surface and an abrasion-resistant cladding covering the forward facing surface. The bluff body suitably also has a projection extending downstream from the forward-facing surface. The bluff body suitably has an abrasion-resistant cladding covering at least a portion of the projection. In one embodiment, the entire bluff body is completely covered by the abrasion-resistant cladding. The inner surface of a segment of the flowtube can also have abrasion-resistant characteristics.

The sensor comprises a deformation element (111) that is flat at least in sections and has a planar surface (111+) and an opposite planar surface (111 #), a sensor lug (112) extending starting from the first surface (111+) of the deformation element, a connection sleeve (113) extending starting from the deformation element, a transducer element (12), which is arranged within the connection sleeve (113) and contacts the surface (111+) of the deformation element with a contact surface, for generating an electrical sensor signal representing temporally changing movements of the sensor lug and/or temporally changing deformations of the deformation element, as well as fastening means, which are positioned within the connection sleeve (113) and are mechanically connected thereto, for fixing the transducer element (12) in the connection sleeve (113). The fastening means (13) of the sensor according to the invention comprise a spring assembly (131) formed by means of at least two stacked disk springs, wherein the disk springs are elastically deformed by exerting a pressing force which holds the transducer element against the deformation element.

The present invention provides a new and unique apparatus featuring a signal processor or processing module configured to: receive signaling containing information about a fluid flow passing through a pipe that is channelized causing flow variations in the fluid flow; and determine corresponding signaling containing information about a fluid flow characteristic of the fluid flow that depends on the flow variations caused in the fluid flow channelized, based upon the signaling received. The signal processor or processing module may be configured to provide the corresponding signaling, including where the corresponding signaling contains information about the fluid flow characteristic of the fluid flow channelized.

An insertion-type flowmeter adapted for removable insertion into a fluid conduit includes an elongate body having a flow opening and a vortex-generating element disposed within the flow opening at distance from the opening entry that is correlated to the size of the flow opening to define a flow conditioning space in the flow opening between the opening entry and the vortex-generating element.

A filling system for filling a container with a pourable product, comprising: a tank configured to be filled with the pourable product; at least one filling device including a local control unit having a control module configured to selectively allow filling of the container with the pourable product; at least one duct interposed between the tank and the filling device; and at least one vortex flowmeter disposed along the duct and configured to generate a pulse-train detection signal as a function of a flow rate of the pourable product along the duct, wherein the local control unit of the filling device includes a processing module configured to process the detection signal from the at least one vortex flowmeter in order to determine an amount of the pourable product flowing into the container, as a function of a number of pulses of the detection signal.

A multiphase flowmeter for detection of fluid flow by monitoring of vortex frequency or perturbation time of flight. The flowmeter includes a bluff body to facilitate formation of vortices during a consistent phase of a flowing fluid. Thus, monitoring frequency of the vortices may be employed to ascertain flowrate. Further, the bluff body may also facilitate formation of perturbations during transitioning phase of the fluid and include perturbation sensors at multiple known locations along the flow-path. Thus, analysis of perturbation detection times at the different locations may be used to ascertain flowrate even in the absence of vortices.

An electronic flow meter that is configured to use localized flow conditions to determine volumetric flow. The embodiments may include a body forming a pass-through channel and a by-pass channel; a semiconductor device comprising a sensor disposed proximate the by-pass channel, the sensor configured to generate a signal with data that reflects localized pressure and localized temperature of a stream in the by-pass channel; and a processing component coupled with the sensor to receive and process the signal so as to identify a flow condition for the stream, select a calculation for volumetric flow rate in response to the flow condition, use data for localized pressure and localized temperature in the calculation to generate a value for the volumetric flow rate; and generate an output with data that reflects the value for the volumetric flow rate.

A vortex meter for measuring a flow rate of a fluid has a flowtube and a bluff body positioned in the flowtube for shedding vortices in the fluid when the fluid flows through the flowtube. The vortex meter has a sensor positioned to detect the vortices. The bluff body has a forward-facing surface and an abrasion-resistant cladding covering the forward facing surface. The bluff body suitably also has a projection extending downstream from the forward-facing surface. The bluff body suitably has an abrasion-resistant cladding covering at least a portion of the projection. In one embodiment, the entire bluff body is completely covered by the abrasion-resistant cladding. The inner surface of a segment of the flowtube can also have abrasion-resistant characteristics.

A method evaluates a frequency spectrum representative of at least one time-dependent signal, the at least one time dependent signal being derived from an output from a measuring device under predetermined measuring device operating conditions. The time-dependent signal, includes a portion being representative of a wanted signal, and a portion being representative of noise. The method includes the steps of determining, based on the frequency spectrum of the signal, a value representative of the noise floor, identifying, based on the frequency spectrum of the signal derived under the predetermined operating condition, a peak component, and if the peak component satisfies a relative peak criterion determined on the basis of the determined value representative of the noise floor, determining the wanted signal by applying a predetermined algorithm. The invention further relates to a method for determining flow of a vortex measuring device, and a vortex sensor.