Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...

Articles Figures Tables About

Pitting index

The API, with help from gear manufacturers, has a 1977 standard (API 613) for rating gears. (See Chapter 4.) A common procedure for comparing and sizing gear is based on the tooth pitting index, the K factor... [Pg.533]

Hatch, G. B., Maximum Self-generated Anodic Current Density as an Inhibitor Pitting Index , III. State Water Surv., Circ. No. 91, 24 (1966) C.A., 66, 8l8l4f Herbsleb, G., Pitting Corrosion on Metals with Elearon-conductive Passive Layers , tVerksl. Korros., 17, 649 (1966) C.A., 66, 5337m ... [Pg.210]

The benefits of LPRM techniques are that the corrosion rates are instantaneous and also provide a pitting index measurement. The capital costs of LPRM equipment can be quite high, especially if several probes and monitors are required, but the probes can be reused and thereafter easily fitted with replacement electrodes. [Pg.385]

The other parameters include the pitting index, which is defined as the standard deviation of current noise divided by the mean current (PI = ci//mean) the power spectral density of a noise, which can be calculated using the MEM (maximum entropy method) and the FFT (fast Fourier... [Pg.790]

LPR Instantaneous Corrosion rate, pitting index Fast Conductive Uniform Simple... [Pg.827]

Corrosion rates obtained with LPR instruments provide rate data directly and within a few minutes. This instrument is well suited to applications where upsets or other accelerated corrosive conditions can be detected quickly so that remedial action can be taken. The corrosion rates obtained with the meter assume uniform corrosion with a tendency to predict pitting attack. Deposits on the electrodes can bias the pitting index value. If the index value is high, the probe should be removed and the electrode visually examined for debris. Bridging the electrodes with conductive deposits will affect both the general corrosion value and the pitting index. [Pg.829]

The advantage of the ER meters is their ability to measure corrosion in liquids, vapor phases, and in inaccessible locations. The liquid does not have to be conductive or have a minimum conductivity as with the LPR systems. However, corrosion rates are not instantaneously determined. The time frame required to determine corrosion rates is a function of probe element and metal loss. Also, the ER probes are suitable only for uniform corrosion. There is no pit index built into the instrument. Any pits developed on the element will cause rapid penetration and indicate excessively high corrosion rates. [Pg.830]

Chromium, molybdenum, and nitrogen are the most efficient alloying elements for increasing the resistance to crevice (and to pitting) corrosion initiation of stainless alloys (Fe-Ni-Cr-Mo-N-... alloys). A pitting index has been derived that characterizes the resistance of stainless alloys to these forms of corrosion [14] (Fig. 12 [15]) ... [Pg.358]

Several methods have been developed for quantifying dental fluorosis. The most commonly used method is Dean s index [49], which classifies fluorosis on a scale of 0 to 4 as follows class 0, no fluorosis class 1, very mild fluorosis (opaque white areas irregularly covering <25% of the tooth surface) class 2, mild fluorosis (white areas covering 25-50% of the tooth surface) class 3, moderate fluorosis (all surfaces affected, with some brown spots and marked wear on surfaces subject to attrition) and class 4, severe fluorosis (widespread brown stains and pitting). The average score of the two most severely affected teeth is used to derive the classification. Other commonly used methods to rate dental fluorosis include the Thylstrup-Fejerskov Index (TFI) [50] and the tooth surface... [Pg.496]

Furthermore it is the rate of kink motion that controls the process. In Fig. 5 the steps around a pit are square at a certain concentration of Fe+, so they are composed almost entirely of stqps lying in < 001 > directions. When the concentration of Fe is increased the corners of the pits become rounded and the overall rate of motion of the steps is reduced. Since the rounded steps do not lie parallel to a low index direction in the surface, they necessarily contain high concentrations of kinks. The rate of kink nucleation is therefore not limiting the motion of the steps rather it is the rate of kink motion that does so. [Pg.144]

Fig. 4.11c. Subsequent removal of the molecules using the STM tip reveals that their adsorption resnlts in the removal of Cn atoms from the rows of the Cu(llO) snrface structure and the formation of pits in the snrface. Examination of the perimeters of the pits reveals that they have two kinks and that those kinks impart the same handedness to the pits as the kinks on a high Miller index CwQikl) surface. Once again, the chirality of an adsorbed molecnle has been imprinted into the structure of an otherwise achiral snrface. Fig. 4.11c. Subsequent removal of the molecules using the STM tip reveals that their adsorption resnlts in the removal of Cn atoms from the rows of the Cu(llO) snrface structure and the formation of pits in the snrface. Examination of the perimeters of the pits reveals that they have two kinks and that those kinks impart the same handedness to the pits as the kinks on a high Miller index CwQikl) surface. Once again, the chirality of an adsorbed molecnle has been imprinted into the structure of an otherwise achiral snrface.
See other pages where Pitting index is mentioned: [Pg.164]    [Pg.435]    [Pg.119]    [Pg.127]    [Pg.8]    [Pg.231]    [Pg.829]    [Pg.1319]    [Pg.364]    [Pg.164]    [Pg.435]    [Pg.119]    [Pg.127]    [Pg.8]    [Pg.231]    [Pg.829]    [Pg.1319]    [Pg.364]    [Pg.1828]    [Pg.1047]    [Pg.303]    [Pg.129]    [Pg.636]    [Pg.639]    [Pg.290]    [Pg.91]    [Pg.78]    [Pg.41]    [Pg.440]    [Pg.557]    [Pg.67]    [Pg.501]    [Pg.470]    [Pg.228]    [Pg.323]    [Pg.15]    [Pg.41]    [Pg.1587]    [Pg.2336]    [Pg.2360]    [Pg.344]    [Pg.2287]    [Pg.267]   
See also in sourсe #XX -- [ Pg.299 ]



SEARCH



Pitting rate index

© 2024 chempedia.info