Separation methods and systems for converting high concentrations of animal wastes and other nutrient-rich organic materials into nutrients and other useful products such as struvite and potassium struvite. Advantageously, the system and methods do not require the addition of external chemicals other than an acid and a base.

Separation methods and systems for converting high concentrations of animal wastes and other nutrient-rich organic materials into nutrients and other useful products such as struvite and potassium struvite. Advantageously, the system and methods do not require the addition of external chemicals other than an acid and a base.

A system for separating solids from fluids, the system including a separator having a deck having a feed inlet and a solids outlet and a plurality of screens disposed on the deck. Also, an image sensor disposed proximate the solids outlet, the image sensor to capture images of the separator, and send the captured mages to a remote location for analysis. Additionally, a method of monitoring a separator, the method including capturing an image of the separator and sending the image of the separator to a control module disposed at a remote location. The method also including analyzing the image with the control module to determine a separation property and modifying the operation of the separator based on the determined separation property.

This disclosure discloses a shaker screen. The shaker screen comprises a frame and at least one screen layer supported by the frame for sieving materials. The frame comprises a rectangular outer support structure, at least one lateral inner support member, and at least one longitudinal inner support member. The lateral inner support member comprises an aperture, and the longitudinal inner support member comprises a groove on a side of the longitudinal inner support member. The lateral inner support member is engaged with the longitudinal inner support member by engaging the aperture on the lateral inner support member and the groove on the longitudinal inner support member.

A method includes depositing, onto a shaker screen, downhole materials and fluids coming to a surface of the borehole as a result of a downhole operation. The downhole materials are separated from the fluids using the shaker screen. Using a radar, an electromagnetic wave is emitted toward a discharge end of the shaker screen or a transit downstream to the shaker. A reflection of the electromagnetic wave reflected off a portion of the downhole materials is detected. A velocity of the downhole materials advancing along the shaker screen toward the discharge end of the shaker screen or on a transit downstream to the shaker is determined. An approximate area occupied by the downhole materials on the shaker screen is determined. A volume of the downhole materials based on the velocity of the downhole materials and the approximate area occupied by the downhole materials on the shaker screen is determined.

Apparatus and methods for degassing and analyzing drilling fluid discharged from a wellbore at an oil and gas wellsite. The apparatus may be a drilling fluid analysis system having a gas analyzer, a fluid analyzer, and a degasser operable to release and separate mud gas entrained in the drilling fluid. The degasser may include a gas-liquid separator having a separator inlet configured to receive the drilling fluid containing the entrained mud gas, a first separator outlet for discharging the mud gas fluidly connected with the gas analyzer, and a second separator outlet for discharging degassed drilling fluid fluidly connected with the fluid analyzer.

The present invention relates to an extraction apparatus for extracting at least one constituent in a substance. The extraction apparatus comprises an extractor, an extraction separator and an extraction condenser. The extractor is used to mix the substance and an extraction fluid, wherein the extraction fluid is a subcritical fluid. The extraction separator is connected to the extractor for receiving and heating the extraction fluid to gasify the extraction fluid and to separate the constituent and the gasified extraction fluid. The extraction condenser is connected to the extraction separator and the extractor for receiving and liquefying the gasified extraction fluid from the extraction separator and sending the liquefied extraction fluid to the extractor.

The present invention relates to an extraction apparatus for extracting at least one constituent in a substance. The extraction apparatus comprises an extractor, an extraction separator and an extraction condenser. The extractor is used to mix the substance and an extraction fluid, wherein the extraction fluid is a subcritical fluid. The extraction separator is connected to the extractor for receiving and heating the extraction fluid to gasify the extraction fluid and to separate the constituent and the gasified extraction fluid. The extraction condenser is connected to the extraction separator and the extractor for receiving and liquefying the gasified extraction fluid from the extraction separator and sending the liquefied extraction fluid to the extractor.

Disclosed is a method for extracting useful substances from shrimp shells. The method comprises: crushing the shrimp shells, mixing the crushed shrimp shells and water, then heating same to 28° C.-35° C., adjusting the pH value to 6.8-7.5, preferably 6.8-7, then adding an alkaline protease and mixing same, heating same to 42° C.-48° C., performing constant-temperature enzymolysis for 50-70 min, and performing sieving to obtain an enzymatic hydrolysate and solid residues; performing centrifugal separation treatment on the enzymatic hydrolysate to obtain a shrimp protein deposit containing astaxanthin; mixing the shrimp protein deposit and water, performing heating while stirring, adjusting the pH value to 6.8-7.0, performing heating to 58° C.-60° C., adding vegetable oil, and performing emulsification for 50-70 min under stirring to obtain an emulsion; and performing centrifugation on the emulsion, and performing delamination to obtain astaxanthin-containing oil in an upper layer, water in a middle layer, and a shrimp protein in a lower layer. The method of the present invention uses waste biomass obtained after shrimps processed as a raw material, and can simultaneously extract several high-value substances, thereby not only improving the utilization rate of the raw material, but also shortening the production cycle; and no organic solvent is added, such that the method is clean, green and environmentally friendly.

Disclosed is a method for extracting useful substances from shrimp shells. The method comprises: crushing the shrimp shells, mixing the crushed shrimp shells and water, then heating same to 28° C.-35° C., adjusting the pH value to 6.8-7.5, preferably 6.8-7, then adding an alkaline protease and mixing same, heating same to 42° C.-48° C., performing constant-temperature enzymolysis for 50-70 min, and performing sieving to obtain an enzymatic hydrolysate and solid residues; performing centrifugal separation treatment on the enzymatic hydrolysate to obtain a shrimp protein deposit containing astaxanthin; mixing the shrimp protein deposit and water, performing heating while stirring, adjusting the pH value to 6.8-7.0, performing heating to 58° C.-60° C., adding vegetable oil, and performing emulsification for 50-70 min under stirring to obtain an emulsion; and performing centrifugation on the emulsion, and performing delamination to obtain astaxanthin-containing oil in an upper layer, water in a middle layer, and a shrimp protein in a lower layer. The method of the present invention uses waste biomass obtained after shrimps processed as a raw material, and can simultaneously extract several high-value substances, thereby not only improving the utilization rate of the raw material, but also shortening the production cycle; and no organic solvent is added, such that the method is clean, green and environmentally friendly.