The probe can include a base and a resistance member extending from the base and onto which a resistance pressure is imparted by a rheological substance when the resistance member is submerged and moved therein. Rheological properties can be obtained using values indicative of the resistance pressure both in a low speed range and in a high speed range.

An apparatus and method to measure and control the slump of concrete by monitoring sensor within the interior surface of a concrete mixer and a liquid flow meter. Data is analyzed by a computer processing unit to determine the slump of the concrete, liquid needed the quantity of concrete within the mixer, the amount of concrete poured, and the starting and ending time of the pour.

The present invention is directed to a cartridge device for a measuring system for measuring viscoelastic characteristics of a sample liquid. In particular a blood sample, comprising a cartridge body having at least one measurement cavity formed therein and having at least one probe element arranged in said at least one measurement cavity for performing a test on said sample liquid; and a cover being attachable on said cartridge body; wherein said cover covers at least partially said at least one measurement cavity and forms a retaining element for retaining said probe element in a predetermined position within said at least one measurement cavity. The invention is directed to a measurement system and a method for measuring viscoelastic characteristics of a sample liquid.

The present invention generally relates to methods for decreasing viscosity, yield stress, or viscosity and yield stress of an asphaltene precipitate-containing aqueous mixture. More specifically, the method comprises applying an effective amount of a water-soluble polymer to an asphaltene precipitate-containing aqueous mixture. The water-soluble polymers comprise polyanion, polycation, and polar water-soluble polymer components. The present invention also relates to water-soluble asphaltene dispersants.

Disclosed are method and system for treating concrete in mixing drums of delivery vehicles having automated rheology (e.g., slump) monitoring systems programmed to dose fluids into concrete based on the monitored rheology. The present invention takes into account a Revolution-To-Discharge value (RTD) which reflects drum rotations needed to move concrete towards and through the mixing drum opening from which concrete is discharged, and also takes into consideration a Volume-Per-Revolution-Upon-Discharge (VPRUD) value which reflects the relation between the rate of discharge and rheology (e.g., slump) of concrete upon discharge. The invention is especially useful for reclaiming concrete in the drum after delivery and can confirm rheology based upon peak (maximum) discharge pressure. The present inventors found surprisingly that discharge pressure readings are useful for recalibrating automated rheology monitoring systems as well as for reporting and/or treating the remainder concrete.

A device for determining a rheological property of a suspension of material comprising fibers for producing containers, comprising a tank for storing the suspension of material comprising fibers and a control unit, wherein the tank comprises a stirring device for stirring the suspension of material comprising fibers and the control unit is designed to determine a rheological property of the suspension of material comprising fibers based on an interaction between the stirring device and the suspension of material comprising fibers.

A system features an acoustic sensor configured to mount on a wall of a mixing drum, sense an acoustic characteristic of a mixture of a slurry, including concrete, contained in a mixing drum when rotating, and provide acoustic sensor signaling containing information about the acoustic characteristic sensed; and a signal processor configured to receive the acoustic sensor signaling, and determine corresponding signaling containing information about a slump characteristic of the mixture of concrete contained in the mixing drum, based upon the signaling received.

A system includes a rheometer probe, a material sample holder, a material feed system, and an accessory ring to perform rheometric experiments. The rheometer probe is configured to extend into the material sample holder to perform a rheological analysis on a material sample therein. The material feed system includes a first material reservoir, a feed implement, and a pump. The feed implement is fluidly coupled with the first material reservoir and positioned to extend into the material sample holder. The pump is operable to selectively transfer materials from the first material reservoir to the material sample holder via the feed implement. The accessory ring is positioned over the open end of the material sample holder and includes a first opening therethrough configured to support the rheometer probe and a second opening therethrough configured to support the feed implement.

Guide bearing with multiple pressure measurement points, System for measuring the viscosity or the Reynolds number of a fluid, with a rod guided by the bearing, Application to monitoring in bio-production. A guide bearing of central axis (X), including a ring, intended to be mounted tightly in a holding structure, the inner surface of which is designed for assembling with a clearance fit, and preferably guiding in translation along the axis X, a tube intended to constitute a measurement rod; an angulation element formed integrally or fixed inside the inner surface of the ring by protruding into it, so as to form an angulation axis of the tube relative to the axis X; a plurality of pressure sensors each designed to measure a point of pressure exerted by a contact point of the tube in one of its angular positions, the pressure sensors being distributed along the inner surface of the ring, on either side of the angulation element.

An apparatus includes a process chip and a dynamic light scattering assembly. The process chip includes a fluid chamber including and an optically transmissive material adjacent to the fluid chamber. The process chip is to be removably positioned in relation to the dynamic light scattering assembly. The dynamic light scattering assembly is to direct the light through the optically transmissive material and into the fluid chamber. The dynamic light scattering assembly is further to receive light scattered by particles in fluid in the fluid chamber in response to the first optical fiber emitting light into the fluid chamber and thereby capture light scattering data. A processor determines viscosity of fluid in the fluid chamber based on the captured light scattering data. The processor also determines one or both of size or size distribution of particles in the fluid based the captured light scattering data.