Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Rubbers blends

Rubber accelerator Rubber antioxidant Rubber bearings Rubber blends Rubber cements Rubber chemicals... [Pg.861]

A pressure-sensitive blended rubber-phenolie adhesive ... [Pg.935]

In order to be effective in imparting various chosen characteristics, all additives employed in a blend must be homogeneously dispersed throughout the blend. The two most commonly employed pieces of equipment for blending rubber and additives are rubber mills and a special type of mechanical mixer known as the Banbury mixer. A typical rubber mill consists of two rolls which rotate toward each... [Pg.444]

Rubber particle size (/i.m) Large particles in blends (%) Rubber phase volume fraction Notched Izod impact strength ft. Ibs/in. Gloss... [Pg.658]

Kresge E.N., Polyolefin thermoplastic elastomer blends. Rubber Chem. TechnoL, 64, 469, 1991. [Pg.163]

FIGURE 11.12 Interaction energy density versus 4-methyl styrene content. (From Raboney, M., Gamer, R.T., Elspass, C.W., and Peiffer, D.G., Phase Behavior of Brominated Poly(Isobutylene-co-4-Methylstyrene)/ General Purpose Rubber Blends. Rubber Division, Proceedings of the American Chemical Society, Nashville, TN, Sept. 29-Oct. 2, 1998, Paper No. 36.)... [Pg.317]

Clarke, J., Clarke, B., and Freakley, P.K. Relationships between Mixing Method, Microstmcture, and Strength of NR BR Blends. Rubber Chem. Technol. 74(1), 1-15, March/April 2001. [Pg.348]

Naskar, M., Debnath, S.C., and Basu, D.K. Effect of Bis (Diisopropyl) Thiophosphoryl Disulfide on the Co-Vulcanization of Carboxyhc Acrylonitrile Butadiene Rubber and Ethylene Propylene Diene Rubber Blends. Rubber Chem. Technol. 75(3), 309-322, July/August 2002. [Pg.349]

Dikland, H.G. and Van Duin, M. Miscibibty of EPM-EPDM Blends, Rubber Chem. Technol. 76(2), 495-506, May/June 2003. [Pg.349]

Suriyachi, P., Kiatkamjomwong, S., and Prasassarkich, P. Natural Rubber-g-Glycidyl Methacrylate/Styrene as a CompatibiUzer in Natural Rubber/PMMA Blends, Rubber Chem. Technol. 77(5), 914—930, November/December 2004. [Pg.350]

N. Tokita, Analysis of Morphology Formation in Elastomer Blends, Rubber Chem. Technol., 50, 292-300 (1977). [Pg.673]

Immiscible Blends. Rubber. Elastomer/elastomer blends are used extensively for commercial applications, particularly in the construction of automobile tires. There is an extensive patent and technological literature on this subject. A recent review (see chapter 19 of Ref. 19 by McDonel, Baranwal, and Andries) summarizes a great deal of this... [Pg.321]

M. Lopez-Manchado, L. Torre and L. M. Kenny, Kinetic analysis of the thermal degradation of PP-EPDM blends. Rubber Chemistry and Technology, 23, 73-84 (2002). [Pg.246]

Material thermoplastics, polymer-polymer blend, polymer-non-polymer blend, rubber. [Pg.384]

This study demonstrated that the final destination of the added core-shell rubber particles, in PC, PA, or both, in the PC-PA binary blend can be controlled by properly selecting the chemical structure of the shell in the core-shell rubber. The unreactive MBS rubber tends to reside in the PC phase and near the vicinity of the PC-PA interface. The reactive MBS-MA rubber can have a chemical reaction with PA end groups and can therefore be retained within the PA phase. High-molecular-weight bisphenol A epoxy resin has proved to be an efficient compatibilizer for PC-PA blends. Rubber-toughening of the PC-PA blend in which PC is the matrix is much more effective than with blends in which PA is the matrix. [Pg.294]

Bondogen. [King Industries Struktol] Sul ic acid and mineral oil blend rubber plasticizer and peptizii agent... [Pg.52]

Thermoplastic elastomeric materials have many important applications including cable and wire especially in mineral, electronic equipment, and automobile industries. The most commonly used method of obtaining thermoplastic elastomer in materials is to toughen plastics by blending rubbers and plastics. Among the most versatile polymer matrices, polyolefins such as PP are the most widely used thermoplastics because of their well-balanced physical and mechanical properties and their easy processability at a relatively low cost, which makes them a versatile material. PP has the disadvantage of... [Pg.437]

Another major utility of these blends are for making diving suits. A few examples are shown in Fig. 15.18. Pro-Am (Fig. 15.18a) is a rubber suit made from NR/EPDM blend. The main features are good stretch characteristics for comfort and three layer construction for durability. It is ideal for sports, military, rescue, and light commercial applications. The Pro-hd (Fig. 15.18b) is tough NR/ EPDM blend rubber suit made to endure the harshest conditions.USIA(Fig. 15.18c) is also a vulcanized rubber suit made from NR/EPDM blend and it is ideal for sports, military, rescue, and light commercial applications. [Pg.467]

Equistar Chemicals Flexathene TP 38KC01. A polypropylene-ethylene copolymer formulated for film applications requiring medium stiffness, excellent impact strength, and high heat resistance. Produced in a proprietary gas-phase process, TP 38KC01 yields a product with greater physical properties and more uniform rubber dispersion than melt-blended rubber compounds. [Pg.167]

P. J. Corish, Fundamental studies of rubber blends. Rubber Chem. Technol. 40, 324 (1967). W. V. Titow and B. J. Lanham, Reinforced Thermoplastics, Appl. Sci. Publ., Barking, Essex, England Wiley, New York, 1975 Halsted Press, New York, 1975. [Pg.691]

Ibarra-Gomez, R., Marquez, A., Valle, L. R R. D., and Rodriguez-Femandez, O. S. 2003. Influence of the blend viscosity and interface energies on the preferential location of CB and conductivity of BR/EPDM blends. Rubber Chemistry and Technology 76 969-978. [Pg.48]

Tokita, N. (1977) Analysis of morphology formation in elastomer blends. Rubber C3tem. Tech.. 50 (2), 292-300. [Pg.102]

Hess, W.M., Scott, C.E., and Callan, J.E. (1967) Carbon black distribution in elastomer blends. Rubber Chem. TedinoL, 40, 371. [Pg.385]

To prepare filled rubber compounds and blends, rubbers were mixed with filler using an internal mixer. During the mixing time samples were taken out for further investigation. Used materials, formulations as well as mixing conditions will be given in details in each part later. [Pg.161]

The rubbers used were S-SBR (Sprintan SLR-4601, Styron Deutschland GmbH), NR (SMR 5, Nordmann Rassmann) and epoxidized natural rubber (ENR 25 and ENR 50, Weber Schaer GmbH Co. KG, Germany) with 25 mol% and 50 mol% epoxy groups, respectively. Carbon black (Corax N220, Evonik Industries) was used as filler. To prepare filled rubber blends, rubbers were mixed with 50 phr filler in an internal mixer. The initial chamber wall temperature T was kept constant at 50 °C. The rotor speed was 50 rpm and the fill factor was 0.6. [Pg.177]

The addition sequence of these ingredients was given in Table 18.8. The blended rubber was removed and cooled at room temperature for 30 min and then mixed using a two-roll mixer. In general, the processing of rubber compounds was performed under constant temperature and pressure. As known. [Pg.449]


See other pages where Rubbers blends is mentioned: [Pg.474]    [Pg.861]    [Pg.714]    [Pg.256]    [Pg.166]    [Pg.15]    [Pg.285]    [Pg.309]    [Pg.312]    [Pg.40]    [Pg.925]    [Pg.173]    [Pg.465]    [Pg.691]    [Pg.1735]    [Pg.329]    [Pg.3081]    [Pg.524]   
See also in sourсe #XX -- [ Pg.33 ]

See also in sourсe #XX -- [ Pg.274 ]




SEARCH



Acrylonitrile-butadiene rubber blending with other polymers

Blend acrylonitrile-butadiene rubber

Blend core-shell rubber

Blend ethylene-acrylic rubber

Blend immiscible, rubber

Blend isoprene rubber

Blending with Natural Rubber

Blends and IPNs of Natural Rubber with Acrylic Plastics

Blends nitrile rubber

Blends of Natural Rubber

Blends of Natural Rubber with Thermoplastics

Blends of rubber

Butyl rubber blends

Chemically Modified Natural Rubber Blends

Chloroprene rubber blends

Chlorosulfonated polyethylene rubber blends

Compounding plastic/rubber blends

Elastomeric rubber-plastic blends

Ethylene-propylene rubbers blends with other elastomers

Ethylene-propylene rubbers blends with plastics

Filler migration rubber blends

Glass transition, rubber-blend-toughened

Halogenated butyl rubbers elastomer blends

High rubber/polyamide blends

In Blends with Rubber Compounds

Layered fillers rubber blends

Miscibility rubber blends

Natural Rubber Blends with Biopolymers

Natural Rubber-Acrylate Blends

Natural rubber EPDM blend

Natural rubber blends

Natural rubber structure immiscible blends

Natural rubber-based blends

Nitrile butadiene rubber blends

Nitrile rubber PVC blends

Nitrile rubber/polyvinyl chloride blend

Non-polar synthetic rubber blends

Nylon 6, acrylate rubber blends

PMMA/rubber blends

PS/rubber blends

Penetrant molecules transport natural rubber based blends

Polar synthetic rubber blends

Polar synthetic rubber blends applications

Polar synthetic rubber blends properties

Polycarbonate-nylon blends, rubber-toughening

Polymer blend ethylene/propylene/diene rubber

Preparation and Characterisation of Novel Electrical Conductive Rubber Blends

Preparation plastic/rubber blends

Recycled rubber blends

Reinforcement rubber blend (

Resin-rubber blends

Rheological behaviour rubber blends

Rubber Toughening of Polyamides by Reactive Blending

Rubber blend composites

Rubber blend composites elastomer phase

Rubber blend composites homogeneity

Rubber blend composites physical properties

Rubber blend composites reinforcing fillers

Rubber blend with gutta percha

Rubber blending modification

Rubber blends Payne effect

Rubber blends dynamic modulus

Rubber blends elastic modulus

Rubber blends elastomers

Rubber blends filler-polymer interaction

Rubber blends loss modulus

Rubber blends properties

Rubber blends storage modulus

Rubber blends sulphur

Rubber blends surface morphology

Rubber blends tensile testing

Rubber blends thermal properties

Rubber blends thermoplastic elastomers

Rubber blends viscoelasticity

Rubber blends vulcanization/grafting

Rubber blends with thermoplastic elastomers

Rubber blends, clay

Rubber industry, blends used

Rubber nanocomposites blending methods

Rubber plastic blend production

Rubber polyurethane elastomer blend

Rubber with thermoplastics, blending

Rubber with thermoplastics, blending waste

Rubber-based blends

Rubber-based blends structural applications

Rubber-based blends tire industry

Rubber-blend systems, investigation

Rubber-blend-toughened epoxy resins

Rubber-blend-toughened structural epoxy adhesives

Rubber-plastic blends

Rubber-toughened blends

Rubber—thermosetting blends

Silica localization in rubber blends

Silicone rubber blend properties

Solution intercalation/blending rubber-clay nanocomposites

Spectroscopy Natural Rubber Based Blends and IPNs

Styrene polybutadiene rubber blend

Styrene-butadiene rubber blend with EPDM

Thermoplastic natural rubber blends

Thermoplastic-recycled rubber blend

Thermoplastic/rubber blends

Thermosetting Blend Systems with Rubbers and Thermoplastics

Viscoelastic Properties of Natural Rubber Based Blends and IPNs

© 2024 chempedia.info