Resin main components

Peat Waxes. Peat waxes are much like montan waxes in that they contain three main components a wax fraction, a resin fraction, and an asphalt fraction. The amount of asphalt in the total yield is influenced strongly by the solvent used in the extraction. Montan waxes contain ca 50 wt % more of the wax fraction than peat waxes, and correspondingly lower percentages of the resin and asphalt fractions. The wax fraction in peat wax is chemically similar to that of the wax fraction in montan wax. 

The anodes most suitable for burying in soil are cylindrical anodes of high-silicon iron of 1 to 80 kg and with diameters from 30 to 110 mm and lengths from 250 to 1500 mm. The anodes are slightly conical and have at the thicker end for the current lead an iron connector cast into the anode material, to which the cable connection is joined by brazing or wedging. This anode connection is usually sealed with cast resin and forms the anode head (see Fig. 7-2). Ninety percent of premature anode failures occur at the anode head, i.e., at the cable connection to the anode [29], Since installation and assembly costs are the main components of the total cost of an... 

Obviously the main component of the adhesive, the resin, will have a very strong effect on this interaction. Failures can be adhesive or cohesive, depending on the substrate and bonding conditions. The test is most meaningful when it is intentionally made to fail cohesively. 

Despite the fact that the two main components of UF-resins are urea and formaldehyde, a broad variety of possible reactions and structures in the resins can be obtained. At the molecular level, the basic characteristics of UF-resins can be explained as follows (1) high reactivity (2) water solubility and dispersibility, which renders the resins ideal for use in the woodworking industry and (3) the reversibility of the aminomethylene link, which also explains the low resistance of the UF-resins against the influence of water and moisture, especially at higher temperatures. This is also one of the reasons for the subsequent formaldehyde emission. 

In addition to the nature of resin and fibre, the laminate properties also depend on the degree of bonding between the two main components and the presence of other additives including air bubbles. Because of this some parts, fabricated by simple hand building techniques, may exhibit strengths no better or even worse than unreinforced materials. This problem is often worst with glass fibres which are therefore normally treated with special finishes to improve the resin-glass bond. 

Cardanol, a main component obtained by thermal treatment of cashew nut shell liquid (CNSL), is a phenol derivative having mainly the meta substituent of a C15 unsaturated hydrocarbon chain with one to three double bonds as the major. Since CNSL is nearly one-third of the total nut weight, a great amount of CNSL is obtained as byproducts from mechanical processes for the edible use of the cashew kernel. Only a small part of cardanol obtained in the production of cashew kernel is used in industrial fields, though it has various potential industrial utilizations such as resins, friction-lining materials, and surface coatings. Therefore, development of new applications for cardanol is very attractive. 

Despite the complexity of the chemical composition of the resinous materials, in a few minutes such techniques provide a mass spectral fingerprint, which highlights the compounds that are the main components in the sample. They avoid any sampling treatment before analysis. They have thus enabled diterpenoid resinous materials from Coniferae, and several triterpenoid materials to be clearly identified. In particular, the DE-MS technique is able to distinguish between different triterpenoid materials such as mastic resin, frankincense resin and birch bark tar. In fact, using PCA on DE-MS mass... 

GC/MS has also been used to investigate acidic and neutral fractions (after alkaline hydrolysis, separation and trimethylsilylation) of a resinous sample collected from a flint flake dated back to the lower Palaeolithic (roughly 200 000 BC) and recovered near Arezzo in Italy [11]. The results show that the organic material recovered on the flint flake was a pitch obtained from birch bark by a pyrolysis type process. In fact, the main components of the acidic fraction are a series of linear a,oo-dicarboxylic acids ranging from 16 to 22 carbon atoms and a series of oo-hydroxycarboxylic acids ranging from 16 to 22 carbon... 

Unsaturated polyester resin (UPR) has two main components, i.e. a polyester and a reactive diluent. 

Figure 9. Liquid chromatogram of crude pine (Pinus montana) resin with tentative structures of the main components. Column 25 cm x 0.22 mm I.D. 3-pm Spherisorb ODS. Mobile phase methanol-water (90 10) adjusted to pH 4 with formic acid. Detection TIC (ions of m/z <40 suppressed). Ion source temperature 230°C.

Figure 10. Mass spectrum of one of the main components of Pinus montana resin in comparison with reference spectrum of isopimarate. Conditions as in Figure 9. (Reproduced with permission from ref. 3. Copyright 1985, Elsevier.)...

Balsam turpentine oil is obtained from the resins of living trees of suitable Pinus species by distillation at atmospheric pressure and temperatures up to 180°C, or by other fractionation methods, which do not change the terpene composition of the resins. Wood turpentine oils, on the other hand, are generally obtained by steam distillation of chopped tree trunks, dead wood, or of resin extracted from this wood. Sulfate turpentine oil is produced as waste in the manufacture of cellulose by the sulfate process and is also a wood turpentine. Pine oil is another wood turpentine oil that is obtained by dry distillation of suitable pine and fir trees, followed by fractionation. However, the term pine oil is nowadays used for a product which is manufactured by hydration of turpentine oil (a-pinene). The resulting product is a mixture of monoterpenes containing o-terpineol as the main component. In addition to many other technical purposes, it is used to a large extent in cheap perfumes for technical applications. 

Exposure-induced Reaction Products. Gel permeation chromatograms of EP, MRS, and EAP were measured before and after exposure at 20 /uC/cm2. The results are summerized in Figures 8 to 10. In the case of EP resist, shown in Figure 8, peaks 1, 2, and 3 represent epoxy novolac dimer, trimer, and tetramer, respectively. Peak 4 represents the main component of the poly(p-vinyl phenol) resin and peak 5 indicates the presence of exposure-induced high molecular weight components in the resin. 

The lignan constituents of the two roots are the same, but the proportions are markedly different. The Indian root contains chiefly podophyllotoxin (Figure 4.21) (about 4%) and 4 -demethylpodophyllotoxin (about 0.45%). The main components in the American root are podophyllotoxin (about 0.25%), p-peltatin (about 0.33%) and a-peltatin (about 0.25%). Desoxypodophyllotoxin and podophyllotoxone are also present in both plants, as are the glucosides of podophyllotoxin, 4-demethylpodophyllotoxin, and the peltatins, though preparation of the resin results in considerable losses of the water-soluble glucosides. 

The resin content of wood and its composition vary considerably, depending on such factors as place of growth, age of the tree, and genetic factors. For example, the resin content of Norway spruce (P/cea abies) is considerably higher for stems grown in the northern than in the southern parts of Scandinavia. The resin content within the same stem also varies, but in a very irregular manner. In all pines, the heartwood contains much more resin than the sapwood, whereas the opposite seems to be true for P/cea species as indicated by data for Norway spruce. The heartwood extractives in both pine and spruce contain resin acids and free fatty acids as main components,... 

We will begin our discussion with the base polymer itself. While it is not an additive, it is obviously a main component of our total system and must be discussed in coloristic terms. From a color standpoint, there are three classifications of resins transparent, translucent, and opaque resins. 

The versatility of asphalt as an adhesive, sealant, and protectant provided early innovators with a unique material with which to advance their primitive technology. Despite the ravages of thousands of years, the main components are still recognizable. Minerals of course remain largely unchanged. Although bitumen is converted extensively to asphaltenes, many resins and even some hydrocarbons are still extant and available for examination. Often the use to which the asphalt was put is still obvious—but not always. 

Spectrometric methods such as IR spectroscopy give information on the main components of the examined samples (dyes, resins and oily liquids). The main pigments are easily detectable in the IR spectra of inks. Because of its non-destructive nature, Raman spectroscopy is applied in forensic investigations for the identification of inks directly on a document, and for determination of the... 

The shell that encloses the kernel is a hard spherical covering 3-5 mm thick. It is used mainly for fuel in copra making. Other products derived from coconut shell are charcoal, activated carbon, filler for synthetic resin, glues, components in mosquito-repellent coils, and decorative items. 

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