The invention relates to a Coriolis mass flow meter, comprising a housing with an inlet and an outlet for a fluid medium, which are arranged along a flow axis (d), at least one measuring tube configured to allow the fluid medium to flow through it in a flow direction (x) and arranged between the inlet and the outlet, wherein the measuring tube includes at least one section with an oval cross-section, so that the measuring tube in this section comprises, perpendicular to the flow direction (x), a longer axis (a) and a shorter axis (b), a vibration exciter (D) configured to cause the measuring tube to vibrate in a vibration direction (f), and two vibration sensors for detection of the movements of the measuring tube, wherein the longer axis (a) of the oval cross-section of the measuring tube is oriented essentially in the vibration direction (f). Moreover, the invention relates to a method for manufacturing a Coriolis mass flow meter with little pressure dependence.

A Coriolis mass flow measuring device includes four bent measuring tubes, two exciter mechanisms, and two sensor arrangements. All four measuring tubes are joined inlet end and outlet end with collectors, where the measuring tubes are connected inlet end and outlet end pairwise with node plates to form oscillators, where the exciter mechanisms are adapted to excite bending oscillation working modes between the two measuring tubes of an oscillator, where the first oscillator and the second oscillator have bending oscillation working modes with first and second working mode eigenfrequencies (f.sub.11, f.sub.12), where the magnitude of the difference of the working mode eigenfrequencies of the two oscillators (|f.sub.11f.sub.12|) amounts to at least 0.1 times, for example, at least 0.2 times and especially at least 0.4 times the lower of the two working mode eigenfrequencies, where the sensor arrangements are adapted to register oscillations of the oscillators.

The invention relates to a temperature measurement system for measuring a temperature of a tube, comprising a temperature sensor contained in a housing having a contact surface which is connected to an outer surface of the tube, wherein the contact surface has a concave form matching a form of the outer surface of the tube, and wherein a temperature-conductive, flexible intermediate layer is arranged between the contact surface and the outer surface of the tube. A further object is a flowmeter, particularly a Coriolis mass flowmeter, comprising the temperature measurement system.

A Coriolis mass flow measuring device and/or density measuring device, comprising: at least two measuring tubes which extend mirror symmetrically to a first mirror plane; at least one exciter mechanism and at least one sensor arrangement for exciting and registering measuring tube oscillations; two terminally located collectors for joining the measuring tubes; a support body for connecting the collectors; and a number of plate-shaped couplers for pairwise connecting of the measuring tubes for forming an oscillator. The measuring tube centerlines of the measuring tubes have two oppositely bent sections and an intermediately lying straight section. The second bent section is arranged on the side of the straight section away from the second mirror plane. The projection of the measuring tube centerline between the intersection with the second mirror plane and the transition between the straight section and the second bent section onto the second mirror plane is not less than the separation between the second mirror plane and the measuring tube centerline at the transition between the straight section and the second bent section, wherein the first bent section has stiffening element, which annularly grip around the measuring tube.

A Coriolis mass flowmeter with a flange connection for connection to an external pipeline, with at least one oscillation generator, with at least two oscillation sensors, with at least two measuring tubes, with at least one flow divider, wherein the flow divider is arranged upstream of the at least two measuring tubes in the direction of flow, and with at least one flow collector, wherein the flow collector is arranged downstream of the at least two measuring tubes. The Coriolis mass flowmeter has at least an active measuring tube and at least a passive measuring tube being provided, the at least one active measuring tube and the at least one passive measuring tube are designed and arranged separately from one another and the at least one oscillation generator and the at least two oscillation sensors are arranged on the at least one active measuring tube.

A method for improving flowmeter (5) reliability is provided. The flowmeter (5) has at least one flow tube (130, 130), at least one pickoff sensor (170L, 170R) attached to the flow tube (130, 130), at least one driver (180L, 180R) attached to the flow tube (130, 130), and meter electronics (20) in communication with the at least one pickoff sensor (170L, 170R) and driver (180L, 180R). The method includes the steps of vibrating at least one flow tube (130, 130) in a drive mode vibration with the at least one driver (180L, 180R), and receiving a sensor signal based on a vibrational response to the drive mode vibration from the at least one pickoff sensor (170L, 170R). At least one flow variable is calculated. A pickoff sensor voltage is measured, and it is determined whether the pickoff sensor voltage is below a predetermined voltage threshold (304). The at least one flow variable is corrected during periods wherein the pickoff sensor voltage is below the predetermined voltage threshold (304).

Provided is a Coriolis flow sensor assembly that includes a flow tube configured to provide a flow path through the flow tube. Further, the Coriolis flow sensor assembly includes a mechanical drive assembly configured to drive an oscillation of the flow tube while fluid is flowing via an oscillation surface. The Coriolis flow sensor assembly includes an interface fixedly coupled to the oscillation surface of the mechanical drive assembly and configured to receive the flow tube.

The method serves for monitoring and/or checking a pressure device having a lumen surrounded by a wall for conveying and/or storing a fluid. To this end, the method comprises a step of registering both a strain of a first wall segment as well as also a strain of at least a second wall segment spaced from the first wall segment, for ascertaining a strain deviation value representing a difference between the strain of the first wall segment and the strain of the second wall segment, as well as a step of using the strain deviation value for ascertaining damage to the wall, as a result of plastic deformation of the wall and/or as a result of wear of the wall. The measuring system of the invention comprises supplementally to the pressure device a first strain sensor affixed on the first wall segment for producing a first strain signal dependent on a time variable strain of the first wall segment as well as at least a second strain sensor affixed on the second wall segment for producing a second strain signal dependent on a time variable strain of the second wall segment. Moreover, the measuring system comprises a transmitter electronics electrically coupled both with the first strain sensor as well as also the second strain sensor. The transmitter electronics is adapted to receive both the first strain signal as well as also the second strain signal as well as to ascertain, with application of the strain signals, damage to the wall.

A measuring transducer includes a support body, a curved oscillatable measuring tube, an electrodynamic exciter, at least one sensor for registering oscillations of the measuring tube, and an operating circuit. The measuring tube has first and second bending oscillation modes, which are mirror symmetric to a measuring tube transverse plane and have first and second media density dependent eigenfrequencies f1, f3 with f3>f1. The measuring tube has a peak secant with an oscillation node in the second mirror symmetric bending oscillation mode. The operating circuit is adapted to drive the exciter conductor loop with a signal exciting the second mirror symmetric bending oscillation mode. The exciter conductor loop has an ohmic resistance R.sub. and a mode dependent mutual induction reactance R.sub.g3 which depends on the position of the exciter. The exciter is so positioned that a dimensionless power factor

[00001]${\mathrm{pc}}_3=\frac{4.Math.R_{}.Math.R_{g.Math..Math.3}}{{\left(R_{}+R_{g.Math..Math.3}\right)}^2}$

has a value of not less than 0.2.

The flow measuring system comprises a measuring transducer having a tube arrangement to convey a flowing fluid, an exciter arrangement for forced mechanical oscillations of the tube arrangement, and a sensor arrangement for registering mechanical oscillations of the tube arrangement. The measuring system further comprises a measuring and operating electronics electrically coupled with the exciter arrangement and the sensor arrangement. The measuring system has two driver circuits and two measurement transmitter circuits. The tube arrangement includes two flow dividers and four connected tubes adapted to be flowed through by the measured substance. The exciter arrangement includes two oscillation exciters, and the sensor arrangement includes four oscillation sensors. The first measurement transmitter circuit processes measurement signals from two oscillation sensors and outputs such to the second measurement transmitter circuit The second measurement transmitter circuit processes oscillation measurement signals of the other two oscillation sensors and ascertains total flow measured values.