Abstract: The invention relates to a microelectromechanical system (MEMS) component or microfluidic component comprising a free-hanging or free-standing microchannel (1), as well as methods for manufacturing such a microchannel, as well as a flow sensor, e.g. a thermal flow sensor or a Coriolis flow sensor, pressure sensor or multi-parameter sensor, valve, pump or microheater, comprising such a microelectromechanical system component or microfluidic component. The MEMS component allows to increase the flow range and/or decrease the pressure drop of for instance a micro Coriolis mass flow meter by increasing the channel diameter, while maintaining its advantages.

Abstract: The invention relates to a micro-Coriolis mass flow sensor, comprising a Coriolis tube having a fixed inlet and a fixed outlet, being fixed in tube fixation means, excitation means for oscillating the Coriolis tube about an excitation axis, detection means (8) for detecting, in use, at least a measure for movements of part of the Coriolis tube, characterized by the detection means (8) comprising one or more strain measurement devices (9, 11) configured for resistive readout being arranged in or on the Coriolis tube.

Abstract: The invention relates to a channel comprising device (1) comprising a channel (10) with a channel wall (15), a channel inlet (11) and a channel outlet (12), wherein the channel wall comprises a polymer (150),wherein the polymer (150) comprises an epoxy-based polymer. The invention further relates to a system (1000) comprising a Coriolis-type flow measuring device(50) comprising the channel comprising device (1) according to the invention and an actuation system (450) configured to let at least part of the channel (10) vibrate thereby causing temporary displacements. The invention, further relates a method for measuring a property of a fluid, wherein the property of the fluid is a property selected form the group consisting of a mass flow rate of the fluid and a density of the fluid.

Abstract: The invention relates to a flow measurement system for determining a flow of a medium, comprising a Coriolis flow sensor, a thermal flow sensor and a processing unit connected thereto. According to the invention, the processing unit is arranged for determining, based on the output signals of both the Coriolis flow sensor and the thermal sensor, at least one of the thermal conductivity and the specific heat capacity of a medium in the flow measurement system. The invention further relates to a method of determining at least one of the thermal conductivity and the specific heat capacity of a medium.

Abstract: The invention relates to a Coriolis flow sensor, comprising at least a Coriolis-tube, wherein the flow sensor comprises an excitation element for causing the tube to oscillate, as well as a detection element for detecting at least a measure of displacements of parts of the tube during operation. In some embodiments, the detection element comprises two detection elements that are positioned on both sides of the Coriolis tube, wherein the detection elements partly overlap each other.

Abstract: The invention relates to a fluid flow device (1), comprising a system chip (11) having a substrate (12), a flow channel (21) defined within said substrate, and a sensor unit (41) connected to said flow channel for determining a property of a fluid in said flow channel. Furthermore, a valve unit (30) is provided within said substrate, for regulating fluid flow through said flow channel. The valve unit comprises a valve chamber (31) defined within said substrate, and a valve member (32) that is movably arranged within the valve chamber. The flow channel has a connection channel part (22) defined within said substrate (12), wherein said connection channel part is connected to said valve unit. Further, control means connected to said valve unit and said sensor unit are provided. The control means are arranged for controlling said valve unit based on signals obtained by said sensor unit.

Abstract: The invention relates to a Coriolis flow sensor, comprising at least a Coriolis-tube, wherein the flow sensor comprises excitation means for causing the tube to oscillate, as well as detection means for detecting at least a measure of displacements of parts of the tube during operation. According to the invention, the detection means comprise two detection elements that are positioned on both sides of the Coriolis tube, wherein the detection elements partly overlap each other.

Abstract: The invention relates to a fluid flow device (1), comprising a system chip (11) having a substrate (12), a flow channel (21) defined within said substrate, and a sensor unit (41) connected to said flow channel for determining a property of a fluid in said flow channel. Furthermore, a valve unit (30) is provided within said substrate, for regulating fluid flow through said flow channel. The valve unit comprises a valve chamber (31) defined within said substrate, and a valve member (32) that is movably arranged within the valve chamber. The flow channel has a connection channel part (22) defined within said substrate (12), wherein said connection channel part is connected to said valve unit. Further, control means connected to said valve unit and said sensor unit are provided. The control means are arranged for controlling said valve unit based on signals obtained by said sensor unit.

Abstract: The invention relates to a method and a system for determining the fractions of a flowing gaseous medium that comprises a known plurality N of known components. The method comprises the steps for determining at least N?1 parameters of a flowing gaseous medium. The N?1 parameters are chosen from a group of quantities comprising mass flow, density, viscosity, and heat capacity. At least N?1 reference values are provided for each of the known N components relating to each of the determined N?1 quantities. The fraction of each of the known components of the supplied gaseous medium is determined through solving of at least N equations. The N equations comprise N?1 equations which describe each determined parameter as a function of the fraction and the reference values, plus an equation that sets the sum of the fractions so as to be equal to 100%.