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HIPSs

M.p. 190-192 C. The enolic form of 3-oxo-L-gulofuranolactone. It can be prepared by synthesis from glucose, or extracted from plant sources such as rose hips, blackcurrants or citrus fruits. Easily oxidized. It is essential for the formation of collagen and intercellular material, bone and teeth, and for the healing of wounds. It is used in the treatment of scurvy. Man is one of the few mammals unable to manufacture ascorbic acid in his liver. Used as a photographic developing agent in alkaline solution. [Pg.43]

A stationary ensemble density distribution is constrained to be a functional of the constants of motion (globally conserved quantities). In particular, a simple choice is pip, q) = p (W (p, q)), where p (W) is some fiinctional (fiinction of a fiinction) of W. Any such fiinctional has a vanishing Poisson bracket (or a connnutator) with Wand is thus a stationary distribution. Its dependence on (p, q) through Hip, q) = E is expected to be reasonably smooth. Quanttun mechanically, p (W) is die density operator which has some fiinctional dependence on the Hamiltonian Wdepending on the ensemble. It is also nonnalized Trp = 1. The density matrix is the matrix representation of the density operator in some chosen representation of a complete orthononnal set of states. If the complete orthononnal set of eigenstates of die Hamiltonian is known ... [Pg.385]

The supersatiiration e = 8 i(ctj) is tlie mean value of hip, which reflects the presence of other subcritical clusters in the system. [Pg.748]

We have seen (Section I) that there are two types of loops that are phase inverting upon completing a round hip an i one and an ip one. A schematic representation of these loops is shown in Figure 10. The other two options, p and i p loops do not contain a conical intersection. Let us assume that A is the reactant, B the desired product, and C the third anchor. In an ip loop, any one of the three reaction may be the phase-inverting one, including the B C one. Thus, the A B reaction may be phase preserving, and still B may be attainable by a photochemical reaction. This is in apparent contradiction with predictions based on the Woodward-Hoffmann rules (see Section Vni). The different options are summarized in Figure 11. [Pg.347]

Note that this program is not exaetly freeware, but it is a site lieense at no eost, whieh means (I think) that you ean t package it and sell it to someone who s not hip enough to get it for himself. [Pg.341]

Projection Hip of the surface can be represented as the union of two sets in accordance with the direction of the axis namely. Hip = H U H. We denote by H the part of the projection of provided that this part is obtained by moving along the positive direction of the axis Respectively, we find H. In particular, the curve Fc belongs both to H and H (see Fig.3.6). We assume the direction of the normal n = ( 1,1 2) to the curve... [Pg.220]

Artichokes Article of manufacture Artifact conservation Artificial colors Artificial flavorings Artificial hip Artificial intelligence... [Pg.73]

Properties of Dense Silicon Carbide. Properties of the SiC stmctural ceramics are shown in Table 1. These properties are for representative materials. Variations can exist within a given form depending on the manufacturer. Figure 2 shows the flexure strength of the SiC as a function of temperature. Sintered or sinter/HIP SiC is the preferred material for appHcations at temperatures over 1400°C and the Hquid-phase densified materials show best performance at low temperatures. The reaction-bonded form is utilized primarily for its ease of manufacture and not for superior mechanical properties. [Pg.319]

Other Industrial Applications. High pressures are used industrially for many other specialized appHcations. Apart from mechanical uses in which hydrauhc pressure is used to supply power or to generate Hquid jets for mining minerals or cutting metal sheets and fabrics, most of these other operations are batch processes. Eor example, metallurgical appHcations include isostatic compaction, hot isostatic compaction (HIP), and the hydrostatic extmsion of metals. Other appHcations such as the hydrothermal synthesis of quartz (see Silica, synthetic quartz crystals), or the synthesis of industrial diamonds involve changing the phase of a substance under pressure. In the case of the synthesis of diamonds, conditions of 6 GPa (870,000 psi) and 1500°C are used (see Carbon, diamond, synthetic). [Pg.76]

With a batch process, such as hot isostatic compaction (HIP), heat exchange as used in a continuous reactor is not possible, and it is common practice to provide a furnace within the pressure vessel which is thermally insulated to ensure that the temperature of the vessel does not rise above 300°C. Most HIP operations involve gas pressures in the range 70—200 MPa (10—29,000 psi) and temperatures of 1250—2000°C, occasionally 2250°C (74). The pressure vessel may have a bore diameter from 27 to 1524 mm (75) and is nearly always provided with threaded closures sealed with O-rings made of elastomer provided the temperature is low enough. [Pg.86]

Densification to what is practically hiU density is achievable for most materials. The resulting mechanical properties are equivalent to wrought parts in similar condition. In some materials, the properties of the HIP product are superior because of reduced anisotropy. [Pg.184]

P/M Tool Steels. In conventionally produced high alloy tool steels (slowly cooled cast ingots), carbide tends to segregate (48). Segregated clusters of carbide persist even after hot working, and cause undesirable effects on tool fabrication and tool performance. P/M tool steels, on the other hand, provide very fine and uniform carbides in the compact, the final bar stock, and the tools. Several tool steel suppHers consoHdate gas-atomized tool steel powder by HIP to intermediate shapes, which are then hot-worked to final mill shapes. Water-atomized tool steel powder is also available (see also T OOL materials). ... [Pg.189]

HDPE by itself is a safe plastic material on account of its chemical inertness and lack of toxicity. Consequently, film and containers made from HDPE are used on a large scale in food and dmg packaging. Moreover, HDPE has been used in prosthetic devices including hip and knee joint replacements (122). [Pg.390]

Noryl. Noryl engineering thermoplastics are polymer blends formed by melt-blending DMPPO and HIPS or other polymers such as nylon with proprietary stabilizers, flame retardants, impact modifiers, and other additives (69). Because the mbber characteristics that are required for optimum performance in DMPPO—polystyrene blends are not the same as for polystyrene alone, most of the HIPS that is used in DMPPO blends is designed specifically for this use (70). Noryl is produced as sheet and for vacuum forming, but by far the greatest use is in pellets for injection mol ding. [Pg.331]

See other pages where HIPSs is mentioned: [Pg.243]    [Pg.611]    [Pg.12]    [Pg.275]    [Pg.386]    [Pg.395]    [Pg.728]    [Pg.149]    [Pg.220]    [Pg.220]    [Pg.220]    [Pg.479]    [Pg.480]    [Pg.480]    [Pg.352]    [Pg.311]    [Pg.318]    [Pg.319]    [Pg.319]    [Pg.322]    [Pg.322]    [Pg.322]    [Pg.322]    [Pg.322]    [Pg.205]    [Pg.87]    [Pg.243]    [Pg.397]    [Pg.56]    [Pg.184]    [Pg.184]    [Pg.188]    [Pg.192]    [Pg.196]    [Pg.239]    [Pg.273]    [Pg.330]   
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Alternatives to Conventional UHMWPE for Hip Arthroplasty

Artificial hip

Artificial hip joints

Biomaterials artificial hips

Blends of PA with ABS, HIPS, and sPS

Congenital hip dislocation

Crazing in HIPS

Flow diagram showing the HIPS process

Free-radical polymerization HIPS process

HIP Petrohemija

HIP diagrams

HIP treatment

HIP-ing

HIPS (high impact

HIPS effect

HIPS examples of modulus retention () versus temperature (C)

HIPS formation

HIPS mass process

HIPS on topside facilities

HIPS, additives

HIPS, additives Flame retardants

HIPS, additives Rubber

HIPS-polymers

High impact polystyrene (HIPS crazing

High impact polystyrene (HIPS graft copolymer

High impact polystyrene (HIPS) process

High impact polystyrene HIPS)

Hip Analysis Suite

Hip Arthroplasty Designs with PTFE

Hip Dysplasia

Hip Infection

Hip Joint Effusion

Hip Pain

Hip arthroplasties

Hip belts

Hip dislocation

Hip extension

Hip extensors

Hip flexors

Hip fracture

Hip implants

Hip joint

Hip joint prostheses

Hip osteoarthritis

Hip protectors

Hip replacement

Hip replacement devices

Hip replacement surgery

Hip resurfacing arthroplasty

Hip simulators

Hip-joint replacement

Hipping

Hipping

Hot Isostatic Pressure (HIP) Sintering

Infant Hip

Metal Alternative Hip Bearings

Methods for Measuring Clinical Wear in Total Hip Arthroplasty

Microstructure formation, HIPS

Modeling HIPS polymerization

Modified High-impact Polystyrene (HIPS) Process

Morphology, HIPS

Optimizing final properties melt flow index in a continuous HIPS process

Periprosthetic hip tissues

Polymerization mass HIPS

Polymers HIPS polystyrene

Polystyrene HIPS

Postoperative Hip

Rate Increase for an 88.9 mm Diameter Extruder Running a HIPS Resin

Ring-Hip

Rose hip

Rose hip seed

Rubber-modified Polystyrene (HIPS) and SAN Copolymers (ABS)

Rubbery-phase morphology, HIPS

Snapping Hip

Special HIPS blends prepared to evaluate the toughening model

Stemless hip prosthesis

Subsea HIPS

Technical parameters of HIPS

Tensile deformation, HIPS

The Clinical Performance of UHMWPE in Hip Replacements

The Origins of UHMWPE in Total Hip Arthroplasty

Total hip

Total hip arthroplasty

Total hip replacement

Transparent HIPS

Traumatic Hip Dislocation

UHMWPE for hip joint implants

Waist-to-hip circumference ratio

Waist-to-hip ratio

Waist—hip ratio

What Is the Composition of an Artificial Hip

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