Ises, list threading

Tees Tees may be cast, forged, or hot- or cold-formed from plate or pipe. Tees are typically stocked with both header (run) ends of the same size. In general, run ends of different sizes are not typically stocked or specified however, occasionally run ends of different sizes are specified in threaded or socket-welded sizes. Branch connections may be full size or reducing sizes. Branch reductions two sizes smaller than the header are routinely stocked, and it is not typically difficult to purchase reducing tees with branches as small as those listed in ASME B16.9 (i.e., approximately one-half the header size). Economics, stress intensification factors, and nondestructive examination requirements typically dictate the branch connection type. 

Different organizations have different formats for the record of invention (i.e., invention disclosure) but some common threads include a brief description of the invention, key dates including conception and reduction to practice, references to key notebook pages, and a list of proposed inventors and their contact information. This document serves as an important record as well as a helpful aid to get the patent agent or attorney started on drafting the patent application. 

Before other functions, e.g. tamper-evidence/resistance, child-resistance, accuracy of delivery, can be discussed, general technical factors associated with ingress and egress need further consideration. Since these are common to seal efficiency (i.e. ingress and egress) and may define seal quality, they were not covered under the headings used earlier. In the example used below a continuous screw threaded container—closure system has been employed as an indication of the typical variables involved. These are listed in Table 11.2 and then briefly discussed. 

The 3D-1D compatibility algorithm (Ito et ai, 1997) is applied to predict the secondary structures by threading at SSThread of DDBJ (http //www.ddbj.nig.ac.jp/E-mail/ ssthread/www service.html). The threading result reports the anuno acid sequence with the predicted secondary structures (H for a-helix E for -strand and C for coil or other). The threading prediction of the query sequence against the structural library chosen from PDB at LIBRA I (http //www.ddbj.nig.ac.jp/E-mail/libra/LIBRA I.html) reports a list of compatible structures and 3D-ID alignment results recording the secondary structures and accessibility. 

The main architecture of the Kimeme Network is shown in Fig. 5 a central Java daemon, called Dispatcher receives requests for computation (i.e., individual solution evaluations) from one or more optimization processes instantiated by (different instances of) the Kimeme GUI. The Dispatcher then distributes the computations, according to various scheduling rules, on a list of available computing nodes (that can be modihed at runtime), which run another Java daemon called Worker. Each Worker defines how many CPUs it has available and how many threads it can launch. Both daemons are platform-independent. 

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