Abstract: A Coriolis mass flow meter of the type including a continuous flexible flow tube fixedly mounted at its ends and adapted for receiving fluid flow. A driver oscillates the flow tube at a fixed frequency. A drive brace is attached at one end to the flow tube mount and at the opposite end to the flow tube substantially at the position of the applied oscillation of the driver. The brace limits the displacement of the flow tube transverse to the direction of the applied oscillation without substantially restricting the motion of the flow tube due to the Coriolis reaction of the fluid to the driver oscillation. The mounting of the flow tube being made by the engagement of gripping portions having bushings therein. The mount limiting transfer of forces acting on the inlet and outlet ends of the flow tube. Resonant pins are provided at each end of the flow tube adjacent the fixed mounting to resiliently clamp the flow tube and fix the resonant frequency thereof throughout its useful life.

Abstract: A method and apparatus for determining mass flow of fluid flowing within a conduit. The conduit is oscillated periodically transverse to the flow therein, and sensors sense the movement of the conduit at discrete, spaced locations on the conduit. The sensors generate periodic signals representative of the movement of the conduit at said locations. The method of the present invention comprises the steps of determining the instantaneous amplitude difference between the signals at a plurality of discrete adjacent intervals (which may or may not be of equal width), determining the product of the absolute value of the instantaneous amplitude difference and the amplitude of the interval for each said interval, determining the sum of said products for each interval over a cycle of oscillation, and generating from the sum a signal representative of mass flow.

Abstract: A mass flow meter for placement in line within a pre-existing process line. The flow meter having a conduit forming a substantially free floating spiral or circular loop which is symmetrical about the axis line defined by the process line. A driving transducer extending radially from a bracket on a support beam which is positioned along the axis line and attached to the inlet and outlet end of the conduit. The driver imparting an alternating deflection to the loop which is substantially perpendicular to the fluid flow within the loop and parallel to the axis line. Sensing transducers are positioned along the periphery of the loop, displaced equidistant from the driving transducer along its circumference for determining the deflection signature of the loop. The deflection of the loop in response to the fluid reaction forces is measured without reference to a specific fixed axis or position of the loop. This acceleration signature is correlated to the mass flow rate of the fluid through the conduit.

Abstract: A symmetrical mass flow meter for placement within a defined fluid stream or pre-existing pipe line which defines an axial line. The flow meter including a single conduit tube which forms two substantially symmetrical and free floating loops between the inlet and the outlet of the flow meter. The flow meter conduit directs the fluid through the first loop and crosses the axial line substantially perpendicular to this line. The second loop directs the fluid from the crossing point and returns it into the defined fluid stream. The conduit is deflected perpendicular to the direction of flow at the crossing of the axial line along the axial line. Sensors are positioned on the periphery of each loop to measure the Coriolis reaction force created by the fluid in response to the central deflection of the conduit. The reaction forces are measured without reference to a specific axis of rotation or a fixed position.