The present disclosure relates to a crude oil flow metering device, which includes a measuring part and a metering part; the measuring part includes a measuring tube and a float assembly; the float assembly is in-built in the measuring tube, and includes a float and a float connection rod integrally connected with the float; an end of the float connection rod is connected to a detection part; the detection part protrudes out of the measuring tube when the float rises from a bottom end; the metering part includes a position detection module and a processing module; the position detection module is arranged in a detection cavity located above the measuring tube and formed by a first housing; when the detection part at the end of the float connection rod extends into the detection cavity, the position detection module detects a position of the detection part at the end of the float connection rod to obtain a float height detection signal; and the processing module calculates a flow rate of measured crude oil according to the float height detection signal. The present disclosure can safely meter the crude oil flow of a crude oil transport pipeline and meet the accuracy of metering crude oil.

The present disclosure relates to a crude oil flow metering device, which includes a measuring part and a metering part; the measuring part includes a measuring tube and a float assembly; the float assembly is in-built in the measuring tube, and includes a float and a float connection rod integrally connected with the float; an end of the float connection rod is connected to a detection part; the detection part protrudes out of the measuring tube when the float rises from a bottom end; the metering part includes a position detection module and a processing module; the position detection module is arranged in a detection cavity located above the measuring tube and formed by a first housing; when the detection part at the end of the float connection rod extends into the detection cavity, the position detection module detects a position of the detection part at the end of the float connection rod to obtain a float height detection signal; and the processing module calculates a flow rate of measured crude oil according to the float height detection signal. The present disclosure can safely meter the crude oil flow of a crude oil transport pipeline and meet the accuracy of metering crude oil.

A flow detection device comprises a fluidic input port connected to a fluidic output port via a channel and a float located within the channel. A specific weight of the float exceeds a specific weight of a fluid injected in the flow detection device. Respective locations of the fluidic input port, of the channel and of the fluidic output port on the flow detection device cause the float to rise within the channel when a sufficient flow of the fluid is injected in the flow detection device. A sensor is provided to detect a position of the float within the channel. The flow detection device may be integrated in a cooling circuit having a cooling device for an electronic device to detect an eventual lack of a flow of a cooling fluid in the cooling circuit. A status of the flow of the cooling fluid is reported to a processor.

A flow detection device comprises a fluidic input port connected to a fluidic output port via a channel and a float located within the channel. A specific weight of the float exceeds a specific weight of a fluid injected in the flow detection device. Respective locations of the fluidic input port, of the channel and of the fluidic output port on the flow detection device cause the float to rise within the channel when a sufficient flow of the fluid is injected in the flow detection device. A sensor is provided to detect a position of the float within the channel. The flow detection device may be integrated in a cooling circuit having a cooling device for an electronic device to detect an eventual lack of a flow of a cooling fluid in the cooling circuit. A status of the flow of the cooling fluid is reported to a processor.

The invention is embodied by a system that employs an inline metering station for (a) measuring both pressure flow and free surface flow in underground conduits without having to physically contact the fluid in the conduit, (b) operating under laminar flow and turbulent flow conditions, (c) providing continuous flow measurement, (d) offering remote data transmission to central control room or mobile device for real-time accessibility (e) detecting line sedimentary deposits (f), making computational adjustments, and (g) alerting maintenance for cleaning. In addition, embodiments of this invention are not disrupted by sewer pipe cleaning and are not limited by sewer flow velocity, depth, or Froude number.

The preferred system comprises a pair of risers (or “tubes”) mounted on top of a buried underground conduit. On top of each riser is a sensor for measuring the distance between the sensor and the surface of the fluid that is flowing below the sensor (the “sensor-fluid distance”). Using as-built conditions, the sensor-fluid distance can be used to find real-time flow depth and velocity through the underground conduit.

The invention is embodied by a system that employs an inline metering station for (a) measuring both pressure flow and free surface flow in underground conduits without having to physically contact the fluid in the conduit, (b) operating under laminar flow and turbulent flow conditions, (c) providing continuous flow measurement, (d) offering remote data transmission to central control room or mobile device for real-time accessibility (e) detecting line sedimentary deposits (f), making computational adjustments, and (g) alerting maintenance for cleaning. In addition, embodiments of this invention are not disrupted by sewer pipe cleaning and are not limited by sewer flow velocity, depth, or Froude number.

The preferred system comprises a pair of risers (or “tubes”) mounted on top of a buried underground conduit. On top of each riser is a sensor for measuring the distance between the sensor and the surface of the fluid that is flowing below the sensor (the “sensor-fluid distance”). Using as-built conditions, the sensor-fluid distance can be used to find real-time flow depth and velocity through the underground conduit.

A flow metering insert (10) for a drip chamber (50) is provided that is suitable for use in intravenous administration. The insert comprises: a primary liquid flow channel with an inlet, an outlet, and a flow-resistant passage between the inlet and the outlet; and a flow indicating channel in communication with the primary liquid flow channel between the inlet and the flow-resistant passage. The flow-resistant passage provides a resistance to liquid flow such that liquid is forced into the flow indicating channel and reaches a height proportional to the rate of liquid flow through the primary liquid flow channel. The flow-resistant passage and the flow indicating channel are at least partially defined by one or more first recesses and/or channels in the insert such that the flow-resistant passage and the flow indicating channel are formed between the insert and a wall of the drip chamber when the insert is inserted into the drip chamber.

A milk meter for measuring a flow rate of milk, having an inlet, an outlet, and a liquid flow path from the inlet to the outlet, the milk meter has a stabilization chamber in the liquid flow path and a float in the stabilization chamber configured to float on the milk, wherein the milk meter is configured so the level of milk in the stabilization chamber depends on the flow rate of the milk flow, the milk meter also has a magnetic unit for generating a magnetic field in the stabilization chamber, which varies in a height direction of the stabilization chamber, the float contains an electronic measuring unit for measuring the strength of the magnetic field, which is a measure of the height within the stabilization chamber of the float and the strength of the magnetic field measures the flow rate of the milk.

A milk meter for measuring a flow rate of milk, having an inlet, an outlet, and a liquid flow path from the inlet to the outlet, the milk meter has a stabilization chamber in the liquid flow path and a float in the stabilization chamber configured to float on the milk, wherein the milk meter is configured so the level of milk in the stabilization chamber depends on the flow rate of the milk flow, the milk meter also has a magnetic unit for generating a magnetic field in the stabilization chamber, which varies in a height direction of the stabilization chamber, the float contains an electronic measuring unit for measuring the strength of the magnetic field, which is a measure of the height within the stabilization chamber of the float and the strength of the magnetic field measures the flow rate of the milk.

Milk meter for measuring a milk flow provided with an inlet the milk flow is supplied to an outlet, a liquid flow path extending from the inlet to the outlet, a stabilization chamber in the liquid flow path and a float therein configured to float on milk. The level of milk in the stabilization chamber depends on the flow rate of the milk flow. At least one sensor device for determining the position of the float in the stabilization chamber for determining the flow rate of the milk flow. The milk meter has an outflow channel and an outflow opening in fluid communication with the outlet via the outflow channel. The sensor device has a first and a second coil which have a fixed distance to each other, and a third coil. The first and second coil and the third coil are displaceable relative to each other.