MECHANICAL AND PROTECTIVE PROPERTIES OF RF DEPOSITED PLASMA POLYMERS

MANIAN, HRISHIKESH

26 May 2005

No description available.

surface modification

Plasma Polymerization

An investigation of the depolymerization of chondroitin sulfate by various microorganisms /

Harvey, Donald Andrew

January 1953

No description available.

Biology

Polymers

Polymerization

Studies on the mechanism of polymerization of dextran by dextran sucrase /

Parnaik, Veena K.

January 1979

No description available.

Chemistry

Polymerization

Dextransucreae

Fundamental studies in reactive processing of polyurethane based polymerizations /

Lee, Yein-ming Leo

January 1986

No description available.

Engineering

Polymerization

Polyurethanes

Urethane-based IPNs and polyureas in reactive polymer processing /

Hsu, Tze-Chien Jeffrey

January 1987

No description available.

Engineering

Polymers

Polymerization

Polyurethanes

Characterization, and optimization of free radical polymerizations in bulk processes /

Huang, Yan-Jyi

January 1987

No description available.

Engineering

Addition polymerization

A visual study of the dynamics of polymer extrusion /

Anastas, Mazen Yacoub

January 1973

No description available.

Engineering

Polymers

Polymerization

Plastics

Cyclodimerization of 1,3-Pentadiene with Homogeneous Nickel Catalyst

Soltani, Morteza

01 January 1980

Piperylene concentrate is a complex mixture of 5-carbon unsaturated hydrocarbons obtained as by-products when naptha or gas oils are cracked. The major component in this mixture is 1,3-pentadiene. The cyclodimerization of 1,3-pentadience in piperylene concentrate by using a nickel catalyst was studied. Various types of ligands were used in the preparation of the nickel catalyst. The effect of each ligand on activity of the catalyst in dimerization of diene, on conversion, and on yield of reaction were investigated. The effect of reaction conditions, such as temperature, pressure, and reaction time, on conversion of monomer, yield of dimer, and selectivity of catalyst were determined. The activity of catalyst on domerization of pure 1,3-pentadiene and isoprene also were studied. Production of various by-products during cyclodimerization of 1,3-pentadiene in piperylene concentrate mixture was a major problem in separation of dimer from these by-products.

Piperylene

Polymerization

Polymers

Chemistry

Scale-up and control of a multi-component emulsion polymerization system

Theron, Jacobus Petrus

03 1900

Thesis (MScEng)--Stellenbosch University, 2000. / ENGLISH ABSTRACT: ABSTRACT: A new emulsion (code name: NW 120) has been developed by Plascon on laboratory scale, for application in the paint industry. It is an environmentally friendly emulsion in which no coalescent solvent is used. It also has a core-shell morphology. Research was undertaken to scale-up (industrialize) the emulsion polymerization of NW 120. The use of a suitable pilot plant was investigated. An available bench-scale pilot plant (RCl, Mettler Toledo) was found to be very expensive. The reactors were very small (R:1.8 l) and the reactor set-ups (reactor, baffies and stirrer configuration) were not similar to the industrial size reactors used by Plascon. A fully computer controlled bench-scale pilot plant was subsequently designed and built at a fraction of the cost of the commercially available set-up. The reactor (5 I) was a scale-down replica (geometrically similar) of the industrial size reactors used by Plascon. The reactor was designed to also serve as a calorimeter. Very good control was achieved over the reaction temperature and addition rates of the monomers and catalyst. Heat loss and heat capacity models were derived for a variation in the reaction temperature between 82.5 - 87.5 °c in order to perform accurate energy balances (calorimeter) around the reactor. The accuracy of the calorimeter was verified at a reaction temperature of 85°C, by measuring the heat that evolved when a sodium hydroxide solution was diluted with water. The accuracy of the calorimeter was found to be extremely good. The pilot plant was commissioned with an industrially manufactured emulsion (code name: AE 446), well known to Plascon. The results obtained in the pilot plant reactor were very similar to those obtained for the full-scale manufacturing of AE 446. It was determined that if geometrical similarity between the pilot plant reactor and the industrial size reactor is preserved and if the correct process conditions (stirring speed, reaction temperature and addition rates of the monomers/catalyst) are maintained, then the direct scale-up of the production ofNW 120, from bench-scale to full-scale, would be possible. The reaction conditions were varied over a wide range, in order to find the optimum process conditions. The stirring speed was varied between 150 - 550 rpm. Shear sensitivity was observed at stirring speeds of 450 rpm and higher. The measured physical properties at 550 rpm were found to be unacceptable. The optimum stirring speed for the desired particle size and viscosity was found to lie between 150 rpm and 250 rpm. The reaction temperature was varied between 70 and 90 DC. The optimum reaction temperature was found to lie between 80 and 90 De. It was possible to successfully reduce the monomer addition time, and hence the reaction times, by increasing the addition rate of the monomers/catalyst, from 4 h to 2 ~ h. The method developed by Klein et al. (1996), for the scale-up of the stirring speed of emulsion polymerization reactions was used to determine the equivalent fullscale stirring speed. The scale-up of NW 120 was subsequently conducted at 85 DC, at a stirring speed of 35 rpm and the monomers/catalyst were added over a period of 4 h. The use of reduced reaction times were not considered in the first scale-up run since at that stage it was not clear whether the heat removal capability of the industrial size reactor would be adequate to cope with the increase in the evolved heat, associated with an increase in the addition rates of the monomers/catalyst. Very good results were obtained. The measured physical properties of NW 120 produced in the industrial size reactor were found to be almost exactly the same as in the pilot plant reactor. / AFRIKAANSE OPSOMMING: 'n Nuwe emulsie (kode naam NW 120) is deur Plascon op laboratorium skaal ontwikkel, vir die gebruik in die verfbedryf. Dit is 'n omgewingsvriendelike produk en geen oplosmiddels word gebruik vir die filmvormingsproses nie. Hierdie projek handeloor die opskalering (industrialisering) van die produksie van NW 120. Die gebruik van 'n geskikte loodsaanleg is eers ondersoek. Daar is gevind dat die beskikbare laboratorium skaalloodsaanleg (RCl, Mettler Toledo) baie duur was. Die reaktore is baie klein (:::::1.81). Die reaktoropstellings (reaktor, keerplate en roerder-konfigurasie) is ook nie in ooreenstemming met die industriële grootte reaktore wat deur Plascon gebruik word nie. 'n Ten volle rekenaarbeheerde loodsaanleg is ontwerp en gebou teen 'n breuk van die koste van soortgelyke kommersieel beskikbare opstellings. Die reaktor (5 I) is 'n skaalmodel (geometries gelykvormig) van die industriële grootte reaktore wat deur Plascon gebruik word. Die reaktor word ook aangewend as 'n kalorimeter. Baie goeie beheer oor die reaktortemperatuur, sowel as die toevoertempo's van die monomere en die katalis is verkry. Hitteverlies en hittekapasiteits modelle is afgelei vir variasies in die reaktortemperatuur tussen 82.5 - 87.5 °c om dit moontlik te maak om akkurate energiebalanse te kan opstel (kalorimeter). Die akkuraatheid van die kalorimeter is getoets by 85°C, deur die verdunningswarmte van 'n natriumhidroksiedoplossing te meet. Daar is gevind dat die kalorimeter baie akkuraat is. 'n Industrieel vervaardigde (plaseon) emulsie (kode naam: AB 446) is gebruik om die loodsaanleg in bedryf te stel. Die resultate wat in die loodsaanleg verkry is, was ongeveer dieselfde as die resultate wat in die industriële reaktore verkry word. Hierdie resultate toon dat indien die reaktore geometries gelykvormig is en indien die regte prosestoestande (roerspoed, reaksietemperatuur en toevoertempo's van die monomere/katalis) gebruik word, dit moontlik sou wees om NW 120 direk op te skaal van loodsaanleg tot volskaal. Die reaksietoestande is gevaneer oor 'n wye bereik om die optimum prosestoestande te probeer verkry. Die roerspoed is gevarieer tussen 150 - 550 opm. Daar is gevind dat die emulsie sleur sensitief is bokant 'n roerspoed van 450 opm. Die gemete fisiese eienskappe by 'n roerspoed van 550 opm was onaanvaarbaar. Die optimum roerspoed in terme van partikelgrootte en viskositeit lê tussen 150 en 250 opm. Die reaksietemperatuur is gevarieer tussen 90 - 70°C. Die optimum temperatuur lê tussen 90 - 80 °C. Dit was moontlik om die monomeer-toevoertyd, m.a.w die reaksietyd, te verminder deur die toevoertempo van die monomere/katalis te verhoog, van 4 tot 2 ~ uur. Die metode wat deur Klein et al. (1996) ontwikkel is vir die opskalering van die roerspoed van 'n emulsiepolimerisasie reaksie is gebruik om die ekwivalente roerspoed vir die opskalering te verkry. Die opskalering van NW 120 is uitgevoer by 'n reaksietemperatuur van 85°C en 'n roerspoed van 35 opm. Die monomere/katalis is toegevoer oor 'n tydperk van 4 uur. Die verkorte reaksietyd is nie oorweeg vir die opskaleringslopie nie omdat dit nog nie seker was of die hitteverwydering van die industriële reaktor effektief genoeg sou wees om die verhoging in die reaksiewarmte-ontwikkeling, wat geassosieer word met 'n verhoging in die toevoertempo van die monomere/katalis, te kan verwyder nie. Baie goeie resultate is verkry. Die gemete fisiese eienskappe van NW 120 wat verkry is in die industriële reaktor was ongeveer dieselfde as dié wat verkry is op die loodsaanleg.

Polymerization

Emulsion polymerization

Dissertations -- Chemical engineering

Theses -- Chemical engineering

Surface grafting of polymers via living radical polymerization techniques; polymeric supports for combinatorial chemistry

Zwaneveld, Nikolas Anton Amadeus, Chemical Engineering & Industrial Chemistry, UNSW

January 2006

The use of living radical polymerization methods has shown significant potential to control grafting of polymers from inert polymeric substrates. The objective of this thesis is to create advanced substrates for use in combinatorial chemistry applications through the use of g-radiation as a radical source, and the use of RAFT, ATRP and RATRP living radical techniques to control grafting polymerization. The substrates grafted were polypropylene SynPhase lanterns from Mimotopes and are intended to be used as supports for combinatorial chemistry. ATRP was used to graft polymers to SynPhase lanterns using a technique where the lantern was functionalized by exposing the lanterns to gamma-radiation from a 60Co radiation source in the presence of carbon tetra-bromide, producing short chain polystyrene tethered bromine atoms, and also with CBr4 directly functionalizing the surface. Styrene was then grafted off these lanterns using ATRP. MMA was graft to the surface of SynPhase lanterns, using g-radiation initiated RATRP at room temperature. It was found that the addition of the thermal initiator, AIBN, successfully increased the concentration of radicals to a level where we could achieve proper control of the polymerization. RAFT was used to successfully control the grafting of styrene, acrylic acid and N,N???-dimethylacrylamide to polypropylene SynPhase Lanterns via a -initiated RAFT agent mediated free radical polymerization process using cumyl phenyldithioacetate and cumyl dithiobenzoate RAFT agents. Amphiphilic brush copolymers were produced with a novel combined RAFT and ATRP system. Polystyrene-co-poly(vinylbenzyl chloride) created using gamma-radiation and controlled with the RAFT agent PEPDA was used as a backbone. The VBC moieties were then used as initiator sites for the ATRP grafting of t-BA to give a P(t-BA) brush that was then hydrolyzed to produce a PAA brush polymer. FMOC loading tests were conducted on all these lanterns to assess their effectiveness as combinatorial chemistry supports. It was found that the loading could be controlled by adjusting the graft ratio of the lanterns and had a comparable loading to those commercially produced by Mimotopes.

ATRP

RAFT

Radiation

polymerization

grafting

living radical polymerization