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Corner

Corner obtained a position with the British Cotton Industry Research Association, Manchester, in 1928, working initially in the rayon department where she developed a fascination with microanalysis. As a result of her acquired background, she was promoted to Head of the Microanalytical Section then in 1945, she obtained a similar post with the British Leather Manufacturers Research Association. Two years later, Comer was invited to become Head of the newly formed Microanalytical Section of the Chemical Research Laboratory (later the National Chemical Laboratory). [Pg.115]

As noted in her obituary by G. R. Davies,51(a) Corner had an unfortunate accident early in life and, Burdened with a severe disability, she had, in addition, more than the usual share of suffering and trouble. In the 1930s, she became a founder member of the Microchemical Club (to be later joined by Isabel Hadfield see Chap. 2). At the time of her death on 4 November 1962, she was Vice-Chairman of the Microchemistry Group of the Society for Analytical Chemistry. [Pg.115]

In every corner of the world, on every subject under the sun. Penguin represents quality and variety - the very best in publishing today. [Pg.437]

Apart from the well-known notch base corner reflection for isotropic welds, the anisotropic case results in a second corner reflection for transducer positions well above the weld. [Pg.149]

Second corner reflection The first corner reflection appears as usual when the transducer is coupled to the probe at a certain distance from the V-butt weld. The second corner reflection appears if the transducer is positioned well above the V-hutt weld. If the weld is made of isotropic material the wavefront will miss (pass) the notch without causing any reflection or diffraction (see Fig. 3(a)) for this particular transducer position. In the anisotropic case, the direction of the phase velocity vector will differ from the 45° direction in the isotropic case. Moreover, the direction of the group velocity vector will no longer be the same as the direction of the phase velocity vector (see Fig. 3(b), 3(c)). This can be explained by comparing the corresponding slowness and group velocity diagrams. [Pg.149]

All metal parts exposed to the room are made of stainless steel and motors and transmissions are IP 65 to withstand the eflfect of the cleaning agents. The design also takes into account the special considerations necessary for food processing machinery with regards to easy accessibility to all parts and the lack of corners, edges, pockets or other food traps , so that the mechanical system can be easily cleaned. [Pg.592]

Depth measurement possibility on complex-contour parts (in the corners, grooves etc.) by training the device in the dialog mode on control items with certain depth cracks... [Pg.652]

The variation of magnetic moment s comer gives the effect similar to their lifting. The sum of corners is to be proportional to ... [Pg.880]

Fig. 5. The dependencies of magnet s corners -A- and magnet s height - - from the distances between its. The shaded area corresponds to the location of sound duct. Fig. 5. The dependencies of magnet s corners -A- and magnet s height - - from the distances between its. The shaded area corresponds to the location of sound duct.
Fig. 7 Edge Echoes and Corner Echoes of STB-Al Specimen for Surface SH Wave Probes... Fig. 7 Edge Echoes and Corner Echoes of STB-Al Specimen for Surface SH Wave Probes...
Figure V-17 shows the apparatus used by Corner and Try son [196] for measurements of Vobs- While their analysis (and literature review) is much more detailed than the foregoing discussion, they concluded that h2/h -4.73 0.05 V at 25°C. Figure V-17 shows the apparatus used by Corner and Try son [196] for measurements of Vobs- While their analysis (and literature review) is much more detailed than the foregoing discussion, they concluded that h2/h -4.73 0.05 V at 25°C.
Buckingham R A and Corner J 1947 Tables of second virial and low-pressure Joule-Thompson coefficients for intermolecular potentials with exponential repulsion Proc. R. Soc. A 189 118... [Pg.216]

Corner J 1948 The second virial coefficient of a gas of non-spherical molecules Proc. R. Soc. A 192 275... [Pg.216]

This substance is familiar as the blue crystalline pentahydrate CUSO4.5H2O. In this crystal, each Cu ion is surrounded by four water molecules at the corners of a square, while the fifth water molecule is held by hydrogen bonds (see Figure 13.8). [Pg.411]

Soreness which may follow ver minor accidents to the eye may he relieved bv placing i drop of castor oil in the corner of the eye. [Pg.527]

In this element the velocity and pressure fields are approximated using biquadratic and bi-linear shape functions, respectively, this corresponds to a total of 22 degrees of freedom consisting of 18 nodal velocity components (corner, mid-side and centre nodes) and four nodal pressures (corner nodes). [Pg.28]

Rectangular Taylor-Hood Bi-quadratic Bi-linear Comers, mid-sides and centre Corners... [Pg.73]

Rectangular Crouzeix-Raviart Bi-quadratic Linear Corners, mid-sides Centre... [Pg.73]

The momentum and continuity equations give rise to a 22 x 22 elemental stiffness matrix as is shown by Equation (3.31). In Equation (3.31) the subscripts I and / represent the nodes in the bi-quadratic element for velocity and K and L the four corner nodes of the corresponding bi-linear interpolation for the pressure. The weight functions. Nr and Mf, are bi-qiiadratic and bi-linear, respectively. The y th component of velocity at node J is shown as iPj. Summation convention on repeated indices is assumed. The discretization of the continuity and momentum equations is hence based on the U--V- P scheme in conjunction with a Taylor-Hood element to satisfy the BB condition. [Pg.84]

Flasks. Flask containing B can be a bottle. A is a round bottom flask, it s better because in a bottle or a flat bottom flask, PdCl2, wich is not dissolved in methanol until it reacts, could be in the corner of flask without reacting. [Pg.87]

Methane is a tetrahedral molecule its four hydrogens occupy the corners of a tetra hedron with carbon at its center We often show three dimensionality m structural for mulas by using a solid wedge ) to depict a bond projecting from the paper toward you and a dashed wedge (i 111 ) for one receding away from you A simple line (—)... [Pg.29]

A vexing puzzle m the early days of valence bond theory concerned the fact that methane is CH4 and that the four bonds to carbon are directed toward the corners of a tetrahedron Valence bond theory is based on the overlap of half filled orbitals of the connected atoms but with an electron configuration of s 2s 2p 2py carbon has only two half filled orbitals (Figure 2 8a) How can it have bonds to four hydrogens ... [Pg.64]

The axes of the sp orbitals point toward the corners of a tetrahedron Therefore sp hybridization of carbon is consistent with the tetrahedral structure of methane Each C—H bond is a ct bond m which a half filled Is orbital of hydrogen over laps with a half filled sp orbital of carbon along a line drawn between them... [Pg.64]

See other pages where Corner is mentioned: [Pg.62]    [Pg.118]    [Pg.145]    [Pg.250]    [Pg.301]    [Pg.327]    [Pg.357]    [Pg.390]    [Pg.405]    [Pg.405]    [Pg.408]    [Pg.152]    [Pg.152]    [Pg.153]    [Pg.640]    [Pg.720]    [Pg.224]    [Pg.56]    [Pg.410]    [Pg.113]    [Pg.490]    [Pg.463]    [Pg.499]    [Pg.500]    [Pg.27]    [Pg.89]    [Pg.239]    [Pg.136]   
See also in sourсe #XX -- [ Pg.239 , Pg.262 , Pg.263 , Pg.264 , Pg.265 ]

See also in sourсe #XX -- [ Pg.193 ]



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Angle and Corner Joints

Atoms edge/corner

Brillouin zone corner

Cell corner

Condensation corners

Corner Boy

Corner Deformation

Corner Harris

Corner Interferometers

Corner atoms

Corner conditions,

Corner cracking

Corner detector

Corner fracture

Corner frequencies

Corner frequency constant

Corner frequency measurement

Corner joints

Corner mesh voltage

Corner point grid

Corner radius

Corner reflector

Corner retroreflector

Corner scheme

Corner singularity

Corner sites

Corner taps

Corner warpage

Corner, Mary

Corner, Michael

Corner-crossing

Corner-cube reflectors

Corner-cutting

Corner-cutting trajectory

Corner-protonated

Corner-protonated cyclopropan

Corner-shared

Corner-sharing

Cornering coefficient

Cube corner

Cube corner array

Cube corner interferometers

Cube corner retroreflector

Cut the corner

Cyclopropane corner protonated

Designs corner

Extreme corner

Factory Mutual Corner Test

Four Corners Power Plant

Four Corners virus

Hydrogen corner sites

Interface corner

Layer structures with corner-sharing octahedral units

Leaf corner

Ledges and Corners

Local solutions, corners

Mold corner

Noise corner

Plastic product design corners

Prism corner-cube

Pseudo re-entrant corner

Pseudo re-entrant corner effect

Re-entrant corner effect

Reentrant corner

Room/corner test

Round Corners

Sharp corner

Small corner configuration

Square Corner Technique

Square corner resistor

The Sharing of Polyhedron Corners, Edges, and Faces

Three-dimensional corner-sharing tetrahedral

Tunneling corner-cutting

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