Process Steam System (Metric Units)

Process Steam System (English Units)

Summary

The objective of this example is to determine the minimum delivery pressure of a process steam supply system.

Topics Covered

• Determining the minimum delivery pressure of a steam supply system.

• Understanding Solution Control sensitivity

Required Knowledge

This example assumes the user has already worked through the Beginner - Air Heating System example, or has a level of knowledge consistent with that topic.  You can also watch the AFT Arrow Quick Start Video on the AFT website, as it covers the majority of the topics discussed in the Beginner: Air Heating System example.

Model File

This example uses the following file, which is installed in the Examples folder as part of the AFT Arrow installation:

• Metric - Process Steam System.aro

Problem Statement

A process steam supply system has two boilers at 20.7 barG (2070 kPa(g)) and 430 deg. C.

All of the pipes in the system have 5 cm of insulation with a thermal conductivity of 0.03 W/m-K, and an ambient air velocity of 11 km/hr. The ambient temperature is 24 deg. C. The pipes are all Steel - ANSI schedule 40. All of the elbows in the system are Smooth, with an r/D of 1.5.

All of the tees in the system should be modeled using the Detailed loss model, with sharp edges.

The system has six users with the following peak flow demands:

1. 18,000 kg/hr

2. 23,000 kg/hr

3. 25,000 kg/hr

4. 25,000 kg/hr

5. 18,000 kg/hr

6. 27,000 kg/hr

Determine the following:

• What is the minimum delivery (stagnation) pressure of the system, and at which user?

Step 1. Start AFT Arrow

From the Start Menu choose the AFT Arrow 10 folder and select AFT Arrow 10.

To ensure that your results are the same as those presented in this documentation, this example should be run using all default AFT Arrow settings, unless you are specifically instructed to do otherwise.

Step 2. Define the Fluid Properties Group

1. Navigate to the Fluid panel in Analysis Setup

2. Define the Fluid panel with the following inputs

   1. Fluid Library = AFT Standard

   2. Fluid = Steam

      1. After selecting, click Add to Model

   3. Equation of State = Redlich-Kwong

   4. Enthalpy Model = Generalized

   5. Specific Heat Ratio Source = Library

Step 3. Define the Pipes and Junctions Group

At this point, the first two groups are completed in Analysis Setup. The next undefined group is the Pipes and Junctions group. To define this group, the model needs to be assembled with all pipes and junctions fully defined. Click OK to save and exit Analysis Setup then assemble the model on the workspace as shown in the figure below.

The system is in place but now we need to enter the properties of the objects. Double-click each pipe and junction and enter the following properties.

Pipe Properties

1. Pipe Model tab

   1. Pipe Material = Steel - ANSI

   2. Pipe Geometry = Cylindrical Pipe

   3. Size = Use table below

   4. Type = Use table below

   5. Friction Model Data Set = Standard

   6. Lengths = Use table below

Pipe	Size (inch)	Type	Length (meters)
1	12	schedule 40	30
2	12	schedule 40	46
10	12	schedule 40	23
101	8	schedule 40	122
102-103	8	schedule 40	229
104	8	schedule 40	76
105	6	schedule 40	30
106	6	schedule 40	15
107	6	schedule 40	23
201	8	schedule 40	76
202-204	8	schedule 40	152
205 & 207	6	schedule 40	15
206	6	schedule 40	23

2. Heat Transfer tab

   1. Heat Transfer Model = Convective Heat Transfer

   2. Number of Insulation Layers = 1 External

   3. Temperature = 24 deg. C

   4. Fluid Velocity = 11 km/hr

   5. Insulation #1 Conductivity = 0.03 W/m-K

   6. Insulation #1 Thickness = 5 cm

Junction Properties

1. J1 & J2 Tanks

   1. J1 Name = Boiler 1

   2. J2 Name = Boiler 2

   3. Elevation = 0 meters

   4. Pressure = 20.7 barG (2070 kPa(g))

   5. Temperature = 430 deg. C

2. All Bends

   1. Elevation = 0 meters

   2. Type = Smooth Bend (flanged or butt-welded)

   3. Angle = 90 Degrees

   4. r/D = 1.5

3. All Tee/Wye

   1. Elevation = 0 meters

   2. Loss Model = Simple

   3. Initial Pressure = 7 barG (on Optional tab)

4. All Assigned Flows

   1. Elevation = 0 meters

   2. Type = Outflow

   3. J106 Name = User 1

   4. J107 Name = User 2

   5. J108 Name = User 3

   6. J206 Name = User 4

   7. J207 Name = User 5

   8. J208 Name = User 6

   1. J106 Flow Rate = 18,000 kg/hr

   2. J107 Flow Rate = 23,000 kg/hr

   3. J108 Flow Rate = 25,000 kg/hr

   4. J206 Flow Rate = 25,000 kg/hr

   5. J207 Flow Rate = 18,000 kg/hr

   6. J208 Flow Rate = 27,000 kg/hr

Note: Sometimes adding initial guesses to pipes or junctions can help difficult solutions converge.

ØTurn on Show Object Status from the View menu to verify if all data is entered. If so, the Pipes and Junctions group in Analysis Setup will have a check mark. If not, the uncompleted pipes or junctions will have their number shown in red. If this happens, go back to the uncompleted pipes or junctions and enter the missing data.

Step 4. Create Workspace Layers

To show the names of the tanks, a new Workspace Layer will be created.

1. Select both tanks on the Workspace using a selection box (dragged from left to right) or holding CTRL while clicking each tank.

2. In the Quick Access Panel, open the Workspace Layers tab.

3. Create a new layer by selecting New Layer and then select the option From Workspace Selections in the drop-down menu. This creates a layer in which the selected objects and their labels are set to be visible.

4. Name the layer Boiler Labels.

5. Edit the layer by selecting it and clicking the gear icon to bring up the Layer Settings window or by double clicking on the layer name.

6. Navigate to the Junction Parameters panel and expand the Commonly Used Junction Parameters list.

7. Double-click Junction Name to add it to the list on the right-hand side. This will add the Junction Name to the tank labels.

8. Close the Layer Settings window.

Another layer will be built to show the discharge pressure at each of the Assigned Flow junctions.

1. Select all of the Assigned Flow junctions on the Workspace.

2. Create a new layer called Discharge Pressures using the From Workspace Selections method.

3. Open Layer Settings for the Discharge Pressures layer and navigate to the Junction Parameters panel.

4. In the list to the left, double-click Junction Name and Pressure Stagnation Outlet (barG) to add them to the list on the right-hand side. Since there is currently no output, the pressure parameter will appear grayed out.

After running the model, this layer will display the discharge pressures on the Workspace.

Step 5. Run the Model

Click Run Model on the toolbar or from the Analysis menu. This will open the Solution Progress window. This window allows you to watch as the AFT Arrow solver converges on the answer. Once the solver has converged, view the results by clicking the Output button at the bottom of the Solution Progress window.

Step 6. Examine the Output

The pipes output section, shown in Figure 2, indicates the minimum delivery stagnation pressure is 9.766 bar (976.6 kPa) at J108.

Pressure results can also be seen on the Workspace from the Discharge Pressures layer that was created earlier, but note that the labels on the Workspace are in units of barG rather than bar.

Step 7. Solution Control Sensitivity

Open Analysis Setup and navigate to the Solution Method panel again. Change the Solution Method to User Specified with an Initial Number of Segments per Pipe as 10 (see Figure 3). Rerun the model, and compare the results to the previous run. 

Repeat the run again with 20 segments, and 40 segments. What are the results?

• With 2 segments, the minimum  (stagnation) pressure is 9.766 bar (976.6 kPa) at J108.

• With 10 segments, the minimum (stagnation) pressure is 9.888 bar (988.8 kPa) at J108.

• With 20 segments, the minimum (stagnation) pressure is 9.892 bar (989.2 kPa) at J108.

• With 40 segments, the minimum (stagnation) pressure is 9.893 bar (989.3 kPa) at J108.

This example points out the fact that some models are sensitive to the Solution Method used. While with most systems changing the solution control will not affect the results, in systems such as this were there are large pressure changes and high Mach numbers, the Solution Control settings can have a strong affect on the results. This is something that ALL engineers should be aware of, and keep in mind when creating computer model solutions.