Thermal mass flow meter

About: Thermal mass flow meter is a research topic. Over the lifetime, 1759 publications have been published within this topic receiving 21878 citations.

Apparatus and method for measuring mass flow rate of a moving medium

Abstract: A mass flow meter is provided for measuring the mass flow rate of a material moving along a flow path. The mass flow meter generates a field of electromagnetic energy through which a material moving along the flow path passes. The mass flow meter includes a receiver that detects an amount of electromagnetic energy reflected from the material which is proportional to the concentration of material moving along the flow path. The amount of electromagnetic energy reflected and an assumed velocity are used to generate a response related to the mass flow rate of the material moving along the flow path.

Composite flow meter

Abstract: This flow meter uses two known flow responsive techniques and combines them in a unique structure and system to form an improved flow meter whose range extends from low to high flow rates. The meter comprises a flow tube with a region of reduced diameter between its inlet and outlet. A microbridge flow sensor of a suitable type known in the art, which responds to thermal changes caused by changes in the flow rate, is located in the region of reduced diameter. A post downstream of the microbridge sensor creates Karman vortices whose frequencies are a function of flow rate and which are detected through ports in the tube by a suitable detector. The output of the microbridge is linear from low flow rates to a mid range and the Karman flow meter output is linear from the mid range to high flow rates. A correction factor is applied to the thermal flow meter output. The correction factor is determined by a ratio of the Karman flow meter output to the thermal output for a flow rate in the mid range, allowing a smooth transition from thermal to Karman outputs and vice versa in the mid range.

Vertical mount mass flow sensor

Abstract: A thermal mass flow meter for measuring flow rate of a fluid includes a conduit that is configured to receive the fluid and that defines a primary flow path between an inlet and an outlet of the conduit. The conduit is bound at least in part by a sensor receiving surface. A thermal sensor tube has a thermal sensing portion that is mounted relative to the sensor receiving surface in a direction substantially perpendicular to both the primary flow path and the sensor receiving surface. When the thermal mass flow meter is mounted in a vertical direction so that fluid within the conduit flows in the vertical direction along the primary flow path, fluid within the sensor tube flows in a horizontal direction so as to substantially prevent thermal siphoning when the sensor tube is heated.

Flow meter and measuring method therefor

Abstract: A flow meter is provided which employs a thermal flow sensor and a correcting flow meter, for example, a Karman vortex flow meter such that the output from the thermal flow sensor is corrected by the Karman vortex flow meter, thereby making it possible to accurately and stably measure the flow rate of fluids in a wide range even if the composition of fluids changes.

Multiphase flow rate measurement using a novel conductance Venturi meter : experimental and theoretical study in different flow regimes

Abstract: Multiphase flows, where two or even three fluids flow simultaneously in a pipe are becoming increasingly important in industry. Although much research has been done to measure the phase flow rates of two-phase flows using a Venturi meter, accurate flow rate measurements of two phase flows in vertical and horizontal pipes at different flow regimes using a Venturi meter remain elusive. In water continuous multiphase flow, the electrical conductance technique has proven attractive for many industrial applications. In gas-water two phase flows, the electrical conductance technique can be used to measure the gas volume fraction. The electrical conductance is typically measured by passing a known electrical current through the flow and then measure the voltage drop between two electrodes in the pipe. Once the current and the voltage drop are obtained, the conductance (or resistance) of the mixture, which depends on the gas volume fraction in the water, can then be calculated. The principal aim of the research described in this thesis was to develop a novel conductance multiphase flow meter which is capable of measuring the gas and the water flow rates in vertical annular flows and horizontal stratified gas water two phase flows. This thesis investigates the homogenous and separated (vertical annular and horizontal stratified) gas-water two phase flows through Venturi meters. In bubbly(approximately homogenous) two phase flow, the universal Venturi meter (nonconductance Venturi) was used in conjunction with the Flow Density Meter, FDM (which is capable of measuring the gas volume fraction at the inlet of the Venturi) to measure the mixture flow rate using the homogenous flow model. Since the separated flow in a Venturi meter is highly complex and the application of the homogenous flow model could not be expected to lead to highly accurate results, a novel conductance multiphase flow meter, which consists of the Conductance Inlet Void Fraction Meter, CIVFM (that is capable of measuring the gas volume fraction at the inlet of the Venturi) and the Conductance Multiphase Venturi Meter, CMVM (that is capable of measuring the gas volume fraction at the throat of the Venturi) was designed and manufactured allowing the new separated flow model to be used to determine the gas and the water flow rates. A new model for separated flows has been investigated. This model was used to calculate the phase flow rates of water and gas flows in a horizontal stratified flow. This model was also modified to be used in a vertical annular flow. The new separated flow model is based on the measurement of the gas volume fraction at the inlet and the throat of the Venturi meter rather than relying on prior knowledge of the mass flow quality x. Online measurement of x is difficult and not practical in nearly all multiphase flow applications. The advantage of the new model described in this thesis over the previous models available in the literature is that the new model does not require prior knowledge of the mass flow quality which makes the measurement technique described in this thesis more practical.