Search results for "Hydraulic retention time"

showing 8 items of 38 documents

Improving membrane photobioreactor performance by reducing light path: operating conditions and key performance indicators

2020

[EN] Microalgae cultivation has been receiving increasing interest in wastewater remediation due to their ability to assimilate nutrients present in wastewater streams. In this respect, cultivating microalgae in membrane photobioreactors (MPBRs) allows decoupling the solid retention time (SRT) from the hydraulic retention time (HRT), which enables to increase the nutrient load to the photobioreactors (PBRs) while avoiding the wash out of the microalgae biomass. The reduction of the PBR light path from 25 to 10 cm increased the nitrogen and phosphorus recovery rates, microalgae biomass productivity and photosynthetic efficiency by 150, 103, 194 and 67%, respectively.The areal biomass product…

INGENIERIA HIDRAULICAEnvironmental EngineeringHydraulic retention timePerformance indicator0208 environmental biotechnologyBiomassPhotobioreactor02 engineering and technologyMicroorganismesWastewater010501 environmental sciencesMembrane photobioreactor01 natural sciencesPhotobioreactorschemistry.chemical_compoundNitrateMicroalgaeBiomassWaste Management and DisposalTECNOLOGIA DEL MEDIO AMBIENTE0105 earth and related environmental sciencesWater Science and TechnologyCivil and Structural EngineeringbiologyOutdoor06.- Garantizar la disponibilidad y la gestión sostenible del agua y el saneamiento para todosEcological ModelingChemical oxygen demandPhosphorusPulp and paper industrybiology.organism_classificationPollution020801 environmental engineeringchemistryWastewaterNitrifying bacteriaVolatile suspended solidsEnvironmental scienceAigües residuals Depuració Tractament biològicLight path
researchProduct

Micropollutants removal in an anaerobic membrane bioreactor and in an aerobic conventional treatment plant

2012

The paper expresses an attempt to tackle the problem due to the presence of micropollutants in wastewater which may be able to disrupt the endocrine system of some organisms. These kinds of compounds are ubiquitously present in municipal wastewater treatment plant (WWTP) effluents. The aim of this paper is to compare the fate of the alkylphenols-APs (4-(tert-octyl)) phenol, t-nonylphenol and 4-p-nonylphenol and the hormones (estrone, 17ß-estradiol and 17¿-ethinylestradiol) in a submerged anaerobic membrane bioreactor (SAMBR) pilot plant and in a conventional activated sludge wastewater treatment plant (CTP). The obtained results are also compared with the results obtained in a previous stud…

INGENIERIA HIDRAULICAUnclassified drugEffluentsExtractionEstrogenic hormonesOxic conditionsMembrane bioreactorDegradationBioreactorsEndocrinologyChemical structureLimit of Detection(4 (tert octyl)) phenolWater PollutantsAnaerobiosisWater Science and TechnologyPilot plantsWaste water managementEstradiolChemistryMembranePhenol derivativeWater samplingPulp and paper industryWaste treatmentEndocrine disruptorWastewaterPollutant removalMembrane bioreactorSewage treatmentActivated sludge plantsAnaerobic exerciseAnaerobic membrane bioreactorActivated sludge plantChromatography GasEnvironmental EngineeringWaste water treatment plantHydraulic retention timeEstroneBioreactorMass fragmentographyPollutantSewage pumping plantsArticlePhenolsEthinylestradiolBioreactorWater treatment plantsEffluentSolid Phase MicroextractionTECNOLOGIA DEL MEDIO AMBIENTE3 nonylphenolChromatography4 nonylphenolAlkylphenol polyoxyethyl etherMembranes ArtificialAlkylphenolsHormoneHormonesActivated sludgeActivated sludgeAnoxic conditionsWater Science and Technology
researchProduct

Simultaneous sludge minimization, biological phosphorous removal and membrane fouling mitigation in a novel plant layout for MBR.

2020

Abstract The integration of one anaerobic reactor in the mainstream (AMSR) of a pre-denitritication-MBR was evaluated with the aim to achieve simultaneous sludge minimization and phosphorous removal. The excess sludge production was reduced by 64% when the AMSR was operated under 8 h of hydraulic retention time (HRT). The highest nutrients removal performances referred to organic carbon (98%), nitrogen (90%) and phosphorous (97%) were obtained under 8 h of HRT. In contrast, prolonged anaerobic-endogenous conditions were found to be detrimental for all nutrients removal performances. Similarly, the lowest membrane fouling tendency (FR = 0.65∙1011 m−1 d−1) was achieved under 8 h of HRT, where…

Membrane foulingEndogenous P-releaseEnvironmental EngineeringHydraulic retention timeNitrogen0208 environmental biotechnologychemistry.chemical_element02 engineering and technology010501 environmental sciencesManagement Monitoring Policy and LawMembrane bioreactor01 natural sciencesWaste Disposal FluidNutrientBioreactorsAnaerobic reactorSludge minimization.Waste Management and Disposal0105 earth and related environmental sciencesSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleSewageChemistryMembrane foulingMembranes ArtificialPhosphorusGeneral MedicinePulp and paper industryBiological nutrients removalNitrogen020801 environmental engineeringMembrane BioReactorPolyphosphate-accumulating organismsJournal of environmental management
researchProduct

A mathematical approach to predict the solids concentration in anaerobic membrane bioreactos (AnMBR): Evaluation of the volatile solids solubilization

2020

[EN] Anaerobic Membrane Bioreactors (AnMBR) are gaining attention as a suitable approach for sustainable low-strength wastewater treatment, as they bring together the advantages of both anaerobic treatments and membrane bioreactors. However, increasing the sludge retention time (SRT) necessary to favor hydrolysis increases the suspended solids concentration potentially leading to decreased permeate flux. Therefore, the availability of a mathematical approach to predict the solids concentration within an AnMBR can be very useful. In this work, a mathematical model describing the volatile solids concentration within the reactor as a function of the operating parameters and the influent charac…

Particulates hydrolysisEnvironmental EngineeringHydraulic retention timeDiffusion0208 environmental biotechnology02 engineering and technologyWastewater010501 environmental sciencesManagement Monitoring Policy and LawWaste Disposal Fluid01 natural sciencesHydrolysisBioreactorsSolubilization constantBioreactorAttentionAnaerobiosisWaste Management and DisposalTECNOLOGIA DEL MEDIO AMBIENTE0105 earth and related environmental sciencesSuspended solidsSewageMathematical modellingChemistryGeneral MedicineSolids prediction020801 environmental engineeringMembraneAnMBRChemical engineeringParticleSewage treatment
researchProduct

Solids and Hydraulic Retention Time Effect on N2O Emission from Moving-Bed Membrane Bioreactors

2018

Biological nutrient removal was operated at different solids (SRT) and hydraulic retention times (HRT) in order to assess their influence on nitrous oxide (N2O) emission from a hybrid moving-bed membrane bioreactor. The observed results show that the N2O production decreased when the SRT/HRT was decreased. The maximum N2O gaseous concentration was measured in the aerobic reactor at the end of phase I, and it decreased through phases II and III. From mass balances over the reactors of the system, the aerated (aerobic and membrane) reactors were the largest producers of N2O, showing that the greater part of N2O was produced during the nitrification process.

Petroleum engineeringHydraulic retention timeBiological nutrient removalSettore ICAR/03 - Ingegneria Sanitaria-AmbientaleChemistryGeneral Chemical Engineering0208 environmental biotechnologyN2OChemistry (all)02 engineering and technologyGeneral Chemistry010501 environmental sciences01 natural sciencesIndustrial and Manufacturing Engineering020801 environmental engineeringMembraneSolids retention timeBioreactorIntegrated fixed-film activated-sludge membrane bioreactorChemical Engineering (all)Moving bedHydraulic retention time0105 earth and related environmental sciences
researchProduct

Methane production from orange peel pressing liquid: A kinetic study

1992

Abstract This paper studies the anaerobic fermentation of orange peel pressing liquid (OPPL), in semi‐continuous digesters under thermophilic conditions (50, 55 and 60°C), using rabbit manure as inoculum which has been previously conditioned to substrate and temperature. Experimental data have been fitted, at each temperature, to the Chen and Hashimoto model. Kinetic parameters governing the process have been obtained. It can be observed that both μm and K decrease when temperature increases, within the studied range, whereas the calculated minimum hydraulic retention time, θm, increases with temperature, as tested experimentally.

PressingChromatographyHydraulic retention timeMethanogenesisChemistryKineticsAnalytical chemistryGeneral MedicineOrange (colour)Kinetic energyManureEnvironmental ChemistryFermentationWaste Management and DisposalWater Science and TechnologyEnvironmental Technology
researchProduct

Impulse response tests in completely mixed tanks and reactors. Key assumptions and steps in mathematical developments.

2010

Stimulus-response technique is a method to obtain the Residence Time Distribution (RTD) for the elements of a fluid passing through a vessel. Generally speaking, in reactor science unsteady-state tests may often appear preferable to steady-state since they are made up of a chain of intermediate ones; but without any theoretical necessity holding. In RTD studies, however, non-steady state tests are the only conceivable ones if conservative tracers are employed, because once a transition is over there is no way to reconstruct it and assess the hydraulic behaviour of the tank. Only a series of tests with non-conservative tracers of known disappearance rate would achieve the task, but at the pr…

Settore ICAR/03 - Ingegneria Sanitaria-AmbientaleHydraulic Retention TimeDead VolumeTracers use
researchProduct

Co-digestion of grass silage and cow manure in a CSTR by re-circulation of alkali treated solids of the digestate.

2008

Three laboratory, continuously stirred tank reactors (CSTRs) co-digesting grass silage and cow manure (forming 30% and 70% of substrate volatile solids (VS), respectively) were operated to evaluate the effects of re-circulating an alkali-treated and untreated solid fraction of the digestate back to the reactors. The CSTRs were operated at an organic loading rate (OLR) of 2 kg VS m(-3) day(-1) and hydraulic retention time (HRT) of 20 days with a semi-continuous mode of feeding. The feasibility of co-digestion with substrate VS containing 30% VS of crop was reinforced, resulting in average specific methane yield of about 180-185 1 CH4 kg(-1) VS. Re-circulation of the solid fraction of digesta…

SilageHydraulic retention timeSilageChemistryConservation of Energy ResourcesGeneral MedicinePoaceaeManureWaste treatmentAnaerobic digestionAnimal scienceBioreactorsBiogasAgronomyDigestateEnvironmental ChemistryAnimalsSodium HydroxideCattleEnergy sourceWaste Management and DisposalCow dungMethaneWater Science and TechnologyEnvironmental technology
researchProduct