Toolbar figure window

P. P Figure zoom functions to magnify or reduce an area of a plot. Used via the mouse from the Figure window toolbar. 

To convert a steady-state simulation into a dynamic simulation, the Dynamic button on the top toolbar shown at the top of Figure 3.56 is clicked. If this button is not showing, go to the top toolbar and click View and Toolbars. The window shown at the bottom of Figure 3.56 opens, on which the box in front of Dynamic is clicked. Then the Dynamic item under the reactor block R1 is clicked, which opens the window shown in Figure 3.57. The Heat Transfer page tab lists six possible options that can be used in the dynamic simulation. In our discussion of these alternatives, we will consider the... 

Figure 1.6 The Setup toolbar, Figure 1.6a, for all worksheet windows other than the initial logo screen. The actions of all the buttons are the same as previously, except for the u button, which on activation leads to the centring device shown in Figure 1.6b.

Now components, physical properties, and feedstream conditions must be specified. Select Data and Setup on the toolbar at the top of the window. The window shown in Figure 2.34 opens. Almost all aspects of the simulation can be accessed from this Data Browser window. The units to use in the simulation are specified in the Units of... 

Note the availability of another Setup command button on the main toolbar of this worksheet its functionality is similar to the Setup button on the main logo sheet, but, as you can see in Figure 1.6, the SET command bar button to save the window size is replaced by a new button, the action of which is to place particular displays on this window and the others accessible using the command buttons of Figure 1.4 as considered best for a particular monitor and the sharpness of the viewer s eyes. This second command bar is included as the Setup option on the main command bar for all the worksheets accessed through the command buttons displayed in Figure 1.5. 

Figure 3-1 The opening window in Microsoft Excel. Note the location of the menu bar, the toolbars, the active cell, and the mouse pointer.

The timescale in Figure 7.26b is fairly small. To get good-looking plots, the plot time interval must be reduced from the default value of 0.01 h. Aspen Dynamics calls this parameter Communication Time, and it can be accessed by going to top toolbar in the Aspen Dynamics window and selecting Run and Run Options. A window opens on which Communication Time can be set. A value of 0.0005 h was used to get the plots shown in Figure 7.26b. This parameter does not affect the results of a dynamic simulation, except for slowing it down somewhat. It only affects the appearance of plots. 

The default numerical integration algorithm uses a variable step size. Switching to a fixed step size eliminated the oscillation problem. To achieve this, go to Run on the upper toolbar in Aspen Dynamics, select Solver Options and click the Integrator page tab. The window shown in Figure 8.43a opens on which the step size can be changed to Fixed. 

Next, left click the top of the Vol% column, which highlights this column. Go to the toolbar at the top of the Aspen Plus window, click Plot and click X-Axis Variable. Highlight each of the columns for the products that you want to plot by holding down the Ctrl key and clicking the top of each column. Then go to the toolbar, click Plot and click Y-Axis Variable. Finally go to the toolbar, click Plot and click Display Plot. Results are shown in Figure 11.43. 

These values are entered by clicking the Dynamics button on the top toolbar, as shown in Figure 4.3. The Dynamic item under the column block turns red, indicating input data is required. Selecting the Reflux Drum page tab opens the window shown in Figure 4.3 where the diameter and the length of the reflux dmm are entered. 

The first thing to do in preparation for exporting into Aspen Dynamics is to click the dynamics button on the top toolbar, as shown in Figure 4.16. Then the Dynamic item under the block for the vessel (called Flash) is clicked, and the window shown in Figure 4.17 opens. This is where the size of the vessel is specified so that the dynamics of the process can be modeled. The Vessel type is selected to be Vertical, and the values of Length and Diameter are entered. 

Figures 1 and 2 show screenshots of OpenMADS GUI. The graphical user interface for OpenMADS has been completely written in Java, and therefore, can run in both Unix- and Windows-based environments. It is composed of three main parts a menu bar (top), drawing area (bottom), and a SysML and MARTE annotation bar or a stochastic Petri Net bar (middle). The upper row of the window contains some menus with commands for file handling, editing, and other model specific commands. A toolbar at the middle contains model...

To begin solving the model, we select the green start icon in the flowsheet toolbar as shown in Figure 5.62. Several initializations step will appear will appear in the lower right comer window of the application. The solution process may take several minutes and the software appears momentarily disabled while solver status messages appear in the lower right comer window. 

We build a subflowsheet environment for the product remixer by returning to the main flowsheet and creating a subflowsheet. We create a sub flowsheet using the FLOWSHEET icon in the Aspen HYSYS toolbar palette shown in Figure 5.94. The new subflowsheet appears in on the main flowsheet as large icon with T marker. We can double click the icon to bring up the subflowsheet connections window. 

To generate ternary plots and to use them for design. Aspen Split is used. This software is imbedded in Aspen Plus and can be accessed by going to the toolbar and clicking Library and References. The window shown in Figure 8.11 opens in which the Aspen Split box should be checked. A new page tab will appear at the bottom of the process flow diagram next to those of the standard unit operation models, which is shown in... 

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