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Square platforms

Precision filoor scales have platform sizes of 1.5 m square or larger, and typically use a lever system to transmit the load to a single EMFC load cell. Capacities range up to 6 t with a minimum of 30,000 displayed divisions. [Pg.332]

Depending on the accessibility afforded by adjacent equipment, aged ladders and access platforms are often quoted as options by vendors. Square body configuration systems (plan view) have square body and plenum sections. Safety handrails surrounding the plenum are standard. Structural supports are usually optional, the height of which depends on system location. Figures 3 and 4 provide sketches of the two basic configurations. [Pg.338]

The square cell is convenient for a model of water because water is quadrivalent in a hydrogen-bonded network (Figure 3.2). Each face of a cell can model the presence of a lone-pair orbital on an oxygen atom or a hydrogen atom. Kier and Cheng have adopted this platform in studies of water and solution phenomena [5]. In most of those studies, the faces of a cell modeling water were undifferentiated, that is no distinction was made as to which face was a lone pair and which was a hydrogen atom. The reactivity of each water cell was modeled as a consequence of a uniform distribution of structural features around the cell. [Pg.41]

Exits to safety chutes should open onto platforms not less than 3 feet square that are equipped with guardrails. [Pg.81]

Over very long periods during the Paleozoic era, the continental shelves were covered by only a few centimeters of water. This was too shallow for currents or tidal exchange to circulate the water. Evaporation increased salinities enough to cause halite and gypsum to precipitate, forming evaporites that extend over thousands of square kilometers and range in thickness from 5 to 10 km. These are referred to as platform evaporites. [Pg.436]

Sch. 2. The utility of the square-planar M(Ph2PCH2CH2PPh2)2 assembly as a platform for electrochemical transformation of ligands in the axial position is further exempKfied in the section on reduction. [Pg.391]

Microfluidic chip devices are also shown to be attractive platforms for performing microscale voltammetric analysis and for integrating voltammetric procedures (linear-sweep, square-wave and adsorptive-stripping voltammetry) with on-chip chemical reactions and fluid manipulations [97]. [Pg.841]

From Eq. (G.6) we obtain appropriate probability information via the system operators T = jl T2), while the transformation formulas (G.4) correspond to proper truth-values consistent with Eq. (G.7). The new eigenvectors here are obtained as a superposition of vectors corresponding to legitimate input values for p = 1. For T2 = 0, Eq. (G.6) gives the classical result p =, i.e., no information at all. Consequently r yields a bias to the no information platform. Note that the operator T, or the truth matrix T, is a nonclassical quantity (operator), which will play a crucial role below serving as the square root of the relevant bias" part of the system operator transforming the input information accordingly. [Pg.109]

Catalysts were some of the first nanostructured materials applied in industry, and many of the most important catalysts used today are nanomaterials. These are usually dispersed on the surfaces of supports (carriers), which are often nearly inert platforms for the catalytically active structures. These structures include metal complexes as well as clusters, particles, or layers of metal, metal oxide, or metal sulfide. The solid supports usually incorporate nanopores and a large number of catalytic nanoparticles per unit volume on a high-area internal surface (typically hundreds of square meters per cubic centimeter). A benefit of the high dispersion of a catalyst is that it is used effectively, because a large part of it is at a surface and accessible to reactants. There are other potential benefits of high dispersion as well— nanostructured catalysts have properties different from those of the bulk material, possibly including unique catalytic activities and selectivities. [Pg.50]

In 2006, we sought to further investigate the influence of the acetylide framework by incorporating a chelating diacetylide into the square planar Pt" platform, namely... [Pg.163]

Terpyridyl has not been the only tridentate ligand used as a platform for producing photoluminescent square-planar Ptn complexes. Che and coworkers published one of the first reports on cyclometallated Ptn complexes, using the NANAC core together... [Pg.175]

Flask Support A heat-resistant board, 5 to 7 mm in thickness and having a 10-cm circular hole, is placed on a suitable ring or platform support and fitted loosely inside the shield to ensure that hot gases from the source of heat do not come in contact with the sides or neck of the flask. A second 5- to 7-mm thick heat-resistant board, 14- to 16-cm square and... [Pg.842]

New architectures with their associated programming models, such as Cray s T3D and the KSR2 machine from Kendall Square Research, seem likely to provide platforms that will aid the development of computational chemistry... [Pg.241]

Figure 12.3 Scanning electron microgrsqihs of various ZnO NR platforms used for biomolecular fluorescence detection, ranging from individual ZnO NRs as well as striped, open-squared, and filled-squared patterns of ZnO NR arrays. The width of each pattern and the repeat distance between patterns are the same as 20 pm, 10 pm, and 5 pm for the striped, open-squared, and filled-squared ZnO NR arrays, reqjectively. Figure 12.3 Scanning electron microgrsqihs of various ZnO NR platforms used for biomolecular fluorescence detection, ranging from individual ZnO NRs as well as striped, open-squared, and filled-squared patterns of ZnO NR arrays. The width of each pattern and the repeat distance between patterns are the same as 20 pm, 10 pm, and 5 pm for the striped, open-squared, and filled-squared ZnO NR arrays, reqjectively.
Figure 12.5 DNA hybridization reactions performed on ZnO NR arrays. (A) Strong fluorescence emission is observed from a sample containing fully complementary ssDNA strands whereas no signal is detected from noncomplementary strands. (B and C) Concentration dependent assays displaying the detection sensitivity of ZnO NR platforms. Data shown in red and blue correspond to assays empolying a covalent and non-covalent linking scheme of DNA strands on ZnO respectively. (D) Fluorescence emission due to duplex DNA formation on open-squared ZnO NR arrays. The easy integration potentkl of ZnO NR arrays into high density platforms is... Figure 12.5 DNA hybridization reactions performed on ZnO NR arrays. (A) Strong fluorescence emission is observed from a sample containing fully complementary ssDNA strands whereas no signal is detected from noncomplementary strands. (B and C) Concentration dependent assays displaying the detection sensitivity of ZnO NR platforms. Data shown in red and blue correspond to assays empolying a covalent and non-covalent linking scheme of DNA strands on ZnO respectively. (D) Fluorescence emission due to duplex DNA formation on open-squared ZnO NR arrays. The easy integration potentkl of ZnO NR arrays into high density platforms is...
See other pages where Square platforms is mentioned: [Pg.12]    [Pg.12]    [Pg.62]    [Pg.64]    [Pg.314]    [Pg.201]    [Pg.223]    [Pg.237]    [Pg.395]    [Pg.363]    [Pg.274]    [Pg.1113]    [Pg.1197]    [Pg.312]    [Pg.42]    [Pg.1248]    [Pg.952]    [Pg.64]    [Pg.90]    [Pg.414]    [Pg.448]    [Pg.81]    [Pg.179]    [Pg.236]    [Pg.145]    [Pg.168]    [Pg.82]    [Pg.869]    [Pg.369]    [Pg.454]    [Pg.1327]   
See also in sourсe #XX -- [ Pg.304 , Pg.305 , Pg.306 , Pg.307 ]

See also in sourсe #XX -- [ Pg.571 , Pg.572 , Pg.573 , Pg.574 ]



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Procedure 9-3 Design of Square and Rectangular Platforms

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