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White pitch

Rocky Mountain (juniper) Pine Austrian Eastern white Pitch Ponderosa Red or Norway Shortleaf Virginia... [Pg.86]

Broke - variations in broke type and broke levels are one of the biggest recurring causes of variation in wet-end chemistry. Broke type can vary due to whether it is before or after a size press or coater, whether it is single-side-coated or doubleside-coated, which recipe of coating mix has been used, etc. Broke treatment to reduce the impact of charge and/or white pitch is always recommended, preferably linked to in-line charge or less preferably, broke flow. [Pg.50]

Manila elemi, white pitch, occasionally dammar generally dammar damar penak,... [Pg.93]

It is available in ultra pure form. Indium is a very soft, silvery-white metal with a brilliant luster. The pure metal gives a high-pitched "cry" when bent. It wets glass, as does gallium. [Pg.116]

Paper. Paper is the principal apphcation for talc throughout the world. It is used as a filler, a coating pigment, and a process aid in pulping and de-inking for pitch and stickies control. As a paper filler, talc is used because of its platiness, softness, whiteness, abiUty to space Ti02, and ink receptivity. [Pg.302]

At the time of Degas visit, the men in Rillieux s white family were briefly involved in the Unification Movement, an abortive attempt by pragmatic white and black businessmen to head off Reconstruction by radical Republicans and voluntarily integrate local governments and public schools. After the Unification Movement failed and Degas returned to France, Rillieux s relations moved on to support whites-only political movements. In a pitched street battle, an all-white militia fought an integrated city police force 32 people died before federal troops restored order. [Pg.41]

Fathollahi, B. and White, J. L., Polarized-light observations of flow-induced microstructures in mesophase pitch, JRheol, 1994,38(5), 1591-1607. [Pg.159]

Figure 5.24 Model of hierarchical self-assembly of chiral rodlike monomers.109 (a) Local arrangements (c-f) and corresponding global equilibrium conformations (c -f) for hierarchical selfassembling structures formed in solutions of chiral molecules (a), which have complementary donor and acceptor groups, shown by arrows, via which they interact and align to form tapes (c). Black and the white surfaces of rod (a) are reflected in sides of helical tape (c), which is chosen to curl toward black side (c ). (b) Phase diagram of solution of twisted ribbons that form fibrils. Scaled variables relative helix pitch of isolated ribbons h hh /a. relative side-by-side attraction energy between fibrils eaur/e. Reprinted with permission from Ref. 109. Copyright 2001 by the National Academy of Sciences, U.S.A. Figure 5.24 Model of hierarchical self-assembly of chiral rodlike monomers.109 (a) Local arrangements (c-f) and corresponding global equilibrium conformations (c -f) for hierarchical selfassembling structures formed in solutions of chiral molecules (a), which have complementary donor and acceptor groups, shown by arrows, via which they interact and align to form tapes (c). Black and the white surfaces of rod (a) are reflected in sides of helical tape (c), which is chosen to curl toward black side (c ). (b) Phase diagram of solution of twisted ribbons that form fibrils. Scaled variables relative helix pitch of isolated ribbons h hh /a. relative side-by-side attraction energy between fibrils eaur/e. Reprinted with permission from Ref. 109. Copyright 2001 by the National Academy of Sciences, U.S.A.
Fasting was necessary he insisted on weeks without meat. As well, Balsamo purchased and sacrificed nine live cockerels (a magical number, as everyone knew). They had to be black, white, and red three of each color in an expression of natural sympathy with the sparkling jewels of the hoard. He d also insisted they undertake ritual ablutions of the skin, followed by the application of special herbs, balms, unguents, and holy oils. All this he accompanied with chants in a high-pitched voice, like the Arabs when they prayed to Allah. [Pg.21]

Barr, Cameron W., Cicada The Other, Other White Meat Epicures Ready to Make a Meal of High-Pitched Pests. See http // www.msnbc.msn.com/id/4752983/ (April 16,2004), for reprint of a story from the The Washington Post. (This article discusses Grubco, Inc.)... [Pg.267]

Figure 10.5. Power number, Np = PgJN3Dsp, against Reynolds number, NR = ND2p/p, for several kinds of impellers (a) helical shape (Oldshue, 1983) (b) anchor shape Oldshue, 1983) (c) several shapes (1) propeller, pitch equalling diameter, without baffles (2) propeller, s = d, four baffles (3) propeller, s = 2d, without baffles (4) propeller, s = 2d, four baffles (5) turbine impeller, six straight blades, without baffles (6) turbine impeller, six blades, four baffles (7) turbine impeller, six curved blades, four baffles (8) arrowhead turbine, four baffles (9) turbine impeller, inclined curved blades, four baffles (10) two-blade paddle, four baffles (11) turbine impeller, six blades, four baffles (12) turbine impeller with stator ring (13) paddle without baffles (data of Miller and Mann) (14) paddle without baffles (data of White and Summerford). All baffles are of width 0.1D [after Rushton, Costich, and Everett, Chem. Eng. Prog. 46(9), 467 (1950)]. Figure 10.5. Power number, Np = PgJN3Dsp, against Reynolds number, NR = ND2p/p, for several kinds of impellers (a) helical shape (Oldshue, 1983) (b) anchor shape Oldshue, 1983) (c) several shapes (1) propeller, pitch equalling diameter, without baffles (2) propeller, s = d, four baffles (3) propeller, s = 2d, without baffles (4) propeller, s = 2d, four baffles (5) turbine impeller, six straight blades, without baffles (6) turbine impeller, six blades, four baffles (7) turbine impeller, six curved blades, four baffles (8) arrowhead turbine, four baffles (9) turbine impeller, inclined curved blades, four baffles (10) two-blade paddle, four baffles (11) turbine impeller, six blades, four baffles (12) turbine impeller with stator ring (13) paddle without baffles (data of Miller and Mann) (14) paddle without baffles (data of White and Summerford). All baffles are of width 0.1D [after Rushton, Costich, and Everett, Chem. Eng. Prog. 46(9), 467 (1950)].
Rubber is vulcanised by treatment with sulphur chloride or by heating with sulphur. In most cases, however, rubber articles are made, not of pure vulcanised rubber, but of the latter mixed with various other substances, organic and inorganic. The organic substances more commonly used are brown and white factis, fatty oils, oxidised oils, waxes, mineral oils, paraffin wax or ceresine, resin or resin oils, bitumens, tar, pitch, starch, and artificial dyes. Very many inorganic compounds may be added either as fillers or to give colour, e.g., talc, kaolin, asbestos, chalk, gypsum, lime. [Pg.325]

Fig. 8. Generation of the form of the helical diffraction pattern. (A) shows that a continuous helical wire can be considered as a convolution of one turn of the helix and a set of points (actually three-dimensional delta-functions) aligned along the helix axis and separated axially by the pitch P. (B) shows that a discontinuous helix (i.e., a helical array of subunits) can be thought of as a product of the continuous helix in (A) and a set of horizontal density planes spaced h apart, where h is the subunit axial translation as in Fig. 7. This discontinuous set of points can then be convoluted with an atom (or a more complicated motif) to give a helical polymer. (C)-(F) represent helical objects and their computed diffraction patterns. (C) is half a turn of a helical wire. Its transform is a cross of intensity (high intensity is shown as white). (D) A full turn gives a similar cross with some substructure. A continuous helical wire has the transform of a complete helical turn, multiplied by the transform of the array of points in the middle of (A), namely, a set of planes of intensity a distance n/P apart (see Fig. 7). This means that in the transform in (E) the helix cross in (D) is only seen on the intensity planes, which are n/P apart. (F) shows the effect of making the helix in (E) discontinuous. The broken helix cross in (E) is now convoluted with the transform of the set of planes in (B), which are h apart. This transform is a set of points along the meridian of the diffraction pattern and separated by m/h. The resulting transform in (F) is therefore a series of helix crosses as in (E) but placed with their centers at the positions m/h from the pattern center. (Transforms calculated using MusLabel or FIELIX.)... Fig. 8. Generation of the form of the helical diffraction pattern. (A) shows that a continuous helical wire can be considered as a convolution of one turn of the helix and a set of points (actually three-dimensional delta-functions) aligned along the helix axis and separated axially by the pitch P. (B) shows that a discontinuous helix (i.e., a helical array of subunits) can be thought of as a product of the continuous helix in (A) and a set of horizontal density planes spaced h apart, where h is the subunit axial translation as in Fig. 7. This discontinuous set of points can then be convoluted with an atom (or a more complicated motif) to give a helical polymer. (C)-(F) represent helical objects and their computed diffraction patterns. (C) is half a turn of a helical wire. Its transform is a cross of intensity (high intensity is shown as white). (D) A full turn gives a similar cross with some substructure. A continuous helical wire has the transform of a complete helical turn, multiplied by the transform of the array of points in the middle of (A), namely, a set of planes of intensity a distance n/P apart (see Fig. 7). This means that in the transform in (E) the helix cross in (D) is only seen on the intensity planes, which are n/P apart. (F) shows the effect of making the helix in (E) discontinuous. The broken helix cross in (E) is now convoluted with the transform of the set of planes in (B), which are h apart. This transform is a set of points along the meridian of the diffraction pattern and separated by m/h. The resulting transform in (F) is therefore a series of helix crosses as in (E) but placed with their centers at the positions m/h from the pattern center. (Transforms calculated using MusLabel or FIELIX.)...
See other pages where White pitch is mentioned: [Pg.16]    [Pg.321]    [Pg.22]    [Pg.23]    [Pg.220]    [Pg.131]    [Pg.132]    [Pg.133]    [Pg.13]    [Pg.16]    [Pg.321]    [Pg.22]    [Pg.23]    [Pg.220]    [Pg.131]    [Pg.132]    [Pg.133]    [Pg.13]    [Pg.193]    [Pg.260]    [Pg.276]    [Pg.366]    [Pg.126]    [Pg.1]    [Pg.52]    [Pg.436]    [Pg.188]    [Pg.329]    [Pg.152]    [Pg.172]    [Pg.213]    [Pg.277]    [Pg.350]    [Pg.465]    [Pg.364]    [Pg.365]    [Pg.1107]    [Pg.1124]    [Pg.46]    [Pg.173]    [Pg.340]   
See also in sourсe #XX -- [ Pg.13 ]



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