Intensification of Operation of Inclined Plate Settler at Fertilizer Plant

Fertilizer plant’s process waters contain high concentrations of nitrogen compounds, such as ammonium and nitrate. Phosphorus and fluorine, which originate from phosphoric acid and rock phosphate (apatite) used in fertilizer production, are also present. Phosphorus and nitrogen are the primary nutrients causing eutrophication of surface waters. At fertilizer plant process waters are held in closed internal circulation. In a scrubber system process waters are used for washing exhaust gases from fertilizer reactors and dry gases from granulation drums as well as for cooling down the fertilizer slurry in neutralization reactor. Solids in process waters are separated in an inclined plate settler by gravitational sedimentation. However, the operation of inclined plate settler has been inadequate. The aim of this thesis was to intensify the operation of inclined plate settler and thus the solids separation e.g. through coagulation and/or flocculation process. Chemical precipitation was studied to reduce the amount of dissolved species in process waters. Specific interest was in precipitation of nitrogen, phosphorus, and fluorine containing specimens. Amounts of phosphorus and fluorine were reduced significantly by chemical precipitation. When compared to earlier studies, annual chemical costs were almost eight times lower. Instead, nitrogen compounds are readily dissolved in water, thus being difficult to remove by precipitation. Possible alternative techniques for nitrogen removal are adsorption, ion exchange, and reverse osmosis. Settling velocities of pH adjusted and flocculated process waters were sufficient for the operation of inclined plate settler. Design principles of inclined plate settler are also presented. In continuation studies, flow conditions in inclined plate settler should be modelled with computational fluid dynamics and suitability of adsorbents, ion exchange resins, and membranes should be studied in laboratory scale tests.

Glukoosi-fruktoosisiirapin kromatografinen fraktiointi

Kuluttajamarkkinoilla on suuri kysyntä vähäkalorisille ruuille ja juomille. Näitä tuotteita voidaan valmistaa mm. korvaamalla makeuttimena perinteisesti käytetty sakkaroosi fruktoosilla joka on 73% makeampi ja sisältää vähemmän kaloreita kuin sakkaroosi. Koska fruktoosi on makeampaa kuin sakkaroosi, sitä tarvitaan vähemmän elintarvikkeissa saman makeusasteen saavuttamiseksi. Glukoosi-fruktoosisiirappia valmistetaan maissista tai sakkaroosista hydrolyysin avulla. Teollisuudessa glukoosi-fruktoosisiirapin fraktiointi tehdään käyttämällä jatkuvatoimista simuloitu liikkuva peti-prosessia (Simulated Moving Bed, SMB-prosessi). Tässä työssä tutkitaan voidaanko kierrätyskromatografiaa (Steady State Recycling , SSR-prosessi) käyttäen fraktioida glukoosi-fruktoosisiirappia tehokkaasti. Fruktoosi erotetaan glukoosista käyttämällä erotusmateriaalina vahvoja kationinvaihtohartseja kalsium-muodossa. Työssä tehtiin kirjallisuusselvitys, jonka perusteella valittiin sopiva erotusmateriaali ja koeolosuhteet. Kokeellisessa osassa glukoosille ja fruktoosille määritettiin adsorptioisotermit Frontal analysis -menetelmällä. Kokeellisesti määritettyihin isotermeihin sovitetut mallit validoitiin ja SSR-prosessi suunniteltiin panoserotuskokeiden avulla. SSR-prosessia mallinnettiin käyttäen MATLAB-ohjelmaa.

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Vibration analysis of a power take-off line

Gear rattle is a phenomenon that occurs when idling or lightly loaded gears collide due to engine’s torque fluctuations. This behaviour is related to vibration behaviour of the transmission system. Aim of this master’s thesis is to evaluate Adams and Adams/Machinery as a simulation tools for modelling the rattle e ect in a transmission system. A case study of tractor’s power take-o driveline, suspected to be prone to rattle, is performed in this work. Modelling methods used by Adams in this type of study are presented in the theory section while simulation model build with the software during this work is presented in the results. The Machinery toolbox is used to create gears and bearings while other model components are created with standard Adams tool set. Geometries and excitations are exported from other softwares. Results were obtained from multiple variations of a base model. These result sets and literature review suggest that Adams/Machinery may not be the most suitable tool for rattle analysis. While the system behaviour was partially captured, for accurate modelling user-written routines must be used which may be more easily performed with other tools. Further research about this topic is required.