The disclosure provides a measurement set-up for a return cement suspension, a construction site arrangement with a measurement set-up, and a method which can be carried out inexpensively, reliably, and easily.

This disclosure provides a system for measuring rheological properties of a fluid including a vessel with a shape defined by the following proportionality: x∝C ×y{circumflex over ( )}((1/n)) wherein the symbol ∝ refers to proportionality, and the variables x and y are coordinates on an x-y cartesian coordinate plane, where x is length and y is height; 2≤n≤4; and C is a constant with dimensions of length, and the vessel includes a hole at or near the y-coordinate minimum; a temperature sensor and a pressure sensor wherein the temperature sensor and pressure sensor are configured to transmit temperature and pressure information to a mobile display device, tablet, or computer, the mobile display device, tablet, or computer comprising memory and a processor and a software application configured to perform processing operations including accepting two input numerical values including density and viscosity measured by the vessel and outputting industry standard dial readings of a conventional rotational rheometer.

Provided are apparatuses and methods for rapid viscometry of whole blood, plasma, and/or whole blood during coagulation. The disclosed technology measures the blood viscosity through the full range of flow rates found in the cardio-vascular system. This in vitro test can be performed on fresh or anticoagulated whole blood to predict the flow properties (e.g., viscosity) anywhere in the body from the aorta to the deep veins of the leg. The result is a flow-rate dependent blood viscosity curve (viscosity profile) that helps the clinician predict and manage the patient's vulnerability to thrombosis and embolism, which is of particular relevance to COVID-19 patients and/or ICU patients.

A blood pump system for persistently increasing the overall diameter and lumen diameter of peripheral veins and arteries by persistently increasing the speed of blood and the wall shear stress in a peripheral vein or artery for a period of time sufficient to result in a persistent increase in the overall diameter and lumen diameter of the vessel is provided. The blood pump system includes a blood pump, blood conduit(s), a control system with optional sensors, and a power source. The pump system is configured to connect to the vascular system in a patient and pump blood at a desired rate and pulsatility. The pumping of blood is monitored and adjusted, as necessary, to maintain the desired elevated blood speed, wall shear stress, and desired pulsatility in the target vessel to optimize the rate and extent of persistent increase in the overall diameter and lumen diameter of the target vessel.

A blood pump system for persistently increasing the overall diameter and lumen diameter of peripheral veins and arteries by persistently increasing the speed of blood and the wall shear stress in a peripheral vein or artery for a period of time sufficient to result in a persistent increase in the overall diameter and lumen diameter of the vessel is provided. The blood pump system includes a blood pump, blood conduit(s), a control system with optional sensors, and a power source. The pump system is configured to connect to the vascular system in a patient and pump blood at a desired rate and pulsatility. The pumping of blood is monitored and adjusted, as necessary, to maintain the desired elevated blood speed, wall shear stress, and desired pulsatility in the target vessel to optimize the rate and extent of persistent increase in the overall diameter and lumen diameter of the target vessel.

A system for monitoring fluid properties in real-time, where the system includes a flow loop having a fluid inlet and fluid outlet. In some embodiments, the flow loop includes a plurality of pipe sections forming the flow loop, where each of pipe section of the plurality of pipe sections are in fluid communication with each other and sensors fluidly coupled to each of the pipe sections perpendicular to fluid flow within each of the pipe sections. In some embodiments, each of the pipe sections has varying inner diameters. In some embodiments, the sensors measure fluid at different velocities corresponding to the varying inner diameters of each of the pipe sections.

A blood pump system for persistently increasing the overall diameter and lumen diameter of peripheral veins and arteries by persistently increasing the speed of blood and the wall shear stress in a peripheral vein or artery for a period of time sufficient to result in a persistent increase in the overall diameter and lumen diameter of the vessel is provided. The blood pump system includes a blood pump, blood conduit(s), a control system with optional sensors, and a power source. The pump system is configured to connect to the vascular system in a patient and pump blood at a desired rate and pulsatility. The pumping of blood is monitored and adjusted, as necessary, to maintain the desired elevated blood speed, wall shear stress, and desired pulsatility in the target vessel to optimize the rate and extent of persistent increase in the overall diameter and lumen diameter of the target vessel.

Systems and methods for determining fluid rheological characteristics of a fluid used in a subsurface operation are provided. The methods include measuring temperature, pressure, and at least one of a flow rate and a flow velocity of the fluid in a first fluid circuit. A model is based on the temperature, the pressures, and the flow rate or flow velocity. The fluid rheological characteristic of the fluid in a second fluid circuit is determined by measuring a temperature and flow rate and/or flow velocity in the second fluid circuit. The rheological characteristic of the fluid is calculated based on the model employing the temperature and the flow rate/flow velocity of the second fluid circuit.

Systems and methods for determining fluid rheological characteristics of a fluid used in a subsurface operation are provided. The methods include measuring temperature, pressure, and at least one of a flow rate and a flow velocity of the fluid in a first fluid circuit. A model is based on the temperature, the pressures, and the flow rate or flow velocity. The fluid rheological characteristic of the fluid in a second fluid circuit is determined by measuring a temperature and flow rate and/or flow velocity in the second fluid circuit. The rheological characteristic of the fluid is calculated based on the model employing the temperature and the flow rate/flow velocity of the second fluid circuit.

The present disclosure provides a low-cost and accurate rheometer system and method capable of determining melt flow rheological properties of polymers, such as from Fused Filament Fabrication (“FFF”) polymeric materials. The device can include a filament feeding system, liquefier for filament melting, force transducer for measuring filament feeding force, and a temperature control system for controlling polymer melt temperatures. An electronic control system can capture data and manage operations. The system can measure a filament velocity and filament force required to extrude the FFF filament for printing. The filament velocity and force data can be used to compute data sets of melt volumetric flow relative to pressure drop across a FFF nozzle. An inverse analysis process transforms the computed data sets through nonlinear curve fitting to determine rheological parameters, independent of the customary calculation of apparent viscosity from shear stress and strain rate, that can assist in controlling the filament deposition.