Scheduling Examples

In this example, there are two reactors in which reactions 1, 2 and 3 can be performed. Equal mean reaction times for the different reactions in each of the reactors imply similar performances for the reactors. The overall process consists of four units, i.e. heater, reactor 1, reactor 2 and separator. In order to handle the usage of feed C in two distinct reactions, i.e. reactions 1 and 3, different states were assigned to each of the streams of feed C, i.e. states, v3 and s4, respectively. In this example, scheduling is performed over an 8-h time horizon. It should be noted that reactors 1 and 2 are suitable for performing reactions 1, 2 and 3, which implies that constraint (2.13) is crucial. Constraints that exhibit similar structure to those presented in example 1 are not repeated. 

Another kind of convenience construct is called an effect. This function can use pre and so can be used to factor out the parts that are common among some of the action specs. For example, schedule course is an action we have decided there will be some interaction for a client to schedule a course. Two possible outcomes of this action are schedule confirmed course and schedule unconfirmed course. We define these as named effects with a single postcondition referring to them by name is exactly equivalent to writing their specifications directly. Effects can be listed on the type box, marked with a stereotype effect , along with the actions. 

Schedule interviews at a convenient time for each witness. Make appointments with witnesses through the appropriate charmels, such as with union and contract personnel. Select a schedule that minimizes contact between witnesses to minimize the sharing of stories between witnesses. For example, schedule each initial interview for 30 minutes. Allow 30 minutes between interviews to complete the documentation of the last interview and prepare for the next one. This gap minimizes contact between witnesses. Adjust the schedule and interview list based on data as they appear. 

Job or task scheduling This requires preparation of time and an action calendar for each order from order receiving to shipment. The job schedule contains a list of tasks to be processed for the styles. Each task planner notes when to start a task and the deadline for that task. The name of the responsible person (department) for the job is listed, for example, scheduling planned cut date and line loading date. 

Discuss the review process and associated logistics (for example, scheduling of interviews and small employee group meetings)... 

In order to test the economic performance of the project to variations in the base case estimates for the input data, sensitivity analysis is performed. This shows how robust the project is to variations in one or more parameters, and also highlights which of the inputs the project economics is more sensitive to. These inputs can then be addressed more specifically. For example if the project economics is highly sensitive to a delay in first production, then the scheduling should be more critically reviewed. 

This procedure is called chloromethylation and will not only turn 1,3-benzodioxole into a methyl chloride but will work equally well in converting plain old benzene into benzyl chloride. Both are important stepping stones towards the production of X and meth. For example, benzyl chloride is a schedule I controlled substance because it will beget benzaldehyde and phenylacetonitrile (a precursor for phenylacetic acid). 

One method of reducing the exposure for sensitive objects is to exhibit them only for limited periods and to maintain a regular rotation schedule. In Japan, for example, some extremely important paintings can only be seen a few days per year. 

Monitor Each CCP. It is necessary to estabflsh a regular schedule for monitoring of each CCP. The schedule could be, for example, once per shift, hourly, or even continuous. Preferably, a pubflshed testing procedure for the monitored parameter should be available. 

If the product is essentially identical to that produced by other manufacturers, then the price is determined principally by the commodity market price. However, contract features such as guaranteed deHvery schedules can influence price. Examples of commodity pricing are petrochemicals, petroleum feedstocks, petroleum products, and primary metals. 

Example 6 Losses with Fittings and Valves It is desired to calculate the liquid level in the vessel shown in Fig. 6-15 required to produce a discharge velocity of 2 m/s. The fluid is water at 20°C with p = 1,000 kg/m and i = 0.001 Pa - s, and the butterfly valve is at 6 = 10°. The pipe is 2-in Schedule 40, with an inner diameter of 0.0525 m. The pipe roughness is 0.046 mm. Assuming the flow is tiirhiilent and taking the velocity profile factor (X = 1, the engineering Bernoulli equation Eq. (6-16), written between surfaces 1 and 2, where the... 

Example 8 Compressible Flow with Friction Losses Calculate the discharge rate of air to the atmosphere from a reservoir at 10 Pa gauge and 20 G through 10 m of straight 2-in Schedule 40 steel pipe (inside diameter = 0.0525 m), and 3 standard radius, flanged 90 elhows. Assume 0.5 velocity heads lost for the elhows. 

Example 9 Pipe Distrihator A 3-in schedule 40 (inside diameter 7.793 cm) pipe is to be used as a distributor for a flow of 0.010 mVs of water (p = 1,000 kg/m, i= 0.001 Pa s). The pipe is 0.7 m long and is to have 10 holes of uniform diameter and spacing along the length of the pipe. The distributor pipe is submerged. Calculate the required hole size to limit maldistribution to 5 percent, and estimate the pressure drop across the distributor. 

Example 10 Response to Instantaneous Valve Closing Compute the wave speed and maximum pressure rise for instantaneous valve closing, with an initial velocity of 2,0 m/s, in a 4-in Schedule 40 steel pipe with elastic modulus 207 X 10 Pa, Repeat for a plastic pipe of the same dimensions, with E = 1.4 X 10 Pa. The liquid is water with P = 2.2 X 10 Pa and p = 1,000 kg/m. For the steel pipe, D = 102,3 mm, b = 6,02 mm, and the wave speed is... 

Instantaneous distillate (or reflux) composition as a function of total accumulated distillate for all three operation steps is plotted in Fig. 13-106. From these results, an alternative schedule of operation steps can he derived to obtain three relatively rich cuts and two intermediate cuts for recycle to the next hatch. One example is as follows ... 

As another example, a fire was said to have been caused by lightning. The report acuTiitted that the grounding was faulty but did not say when it was last checked, if it was scheduled for regular inspection, if there was a specification for the resistance to earth (ground), if employees understood the need for good grounding, and so on. 

In Table 1, drawn up by the author, of abbreviations in common use those in bold type are in the main schedule of BS 3502. In this list the names given for the materials aie the commonly used scientific names. This situation is further complicated by the adoption of a nomenclature by the International Union of Pure and Applied Chemistry for systematic names and a yet further nomenclature by the Association for Science Education which is widely used in British schools but not in industry. Some examples of these are given in Table 2. Because many rubbery materials have been referred to in this book. Tables 3 and 4 list abbreviations for these materials. 

With given contaminant source and sink schedules and outdoor concentrations, concentration evolutions over time can be determined for the individual zones on the basis of the calculated airflow rate values per time step. Further postprocessing allows the determination of accumulated values such as air change rate or concentration histograms (see the later example) or inhaled dose values. 

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