Applies To Product(s): AutoPIPE, Version(s): 2004, XM, & V8i Environment: N/A Area: Modeling Subarea: Original Author: Bentley Technical Support Group Problem: What are some typical modeling approaches for different types of piping? Answer: #1: Coated PIPE (ex. concrete encased steel pipe): There is no accurate way to simulate this analysis. In order to correctly account for the pipe & concrete stiffness, you would need outside program values for total pipe stiffness (pipe & coating), OR, suggest to calculate an equivalent steel thickness by calculating the equivalent moment of inertia. Es*Ie = Es*Is + Ec*Ic Where Es, Ec stand for modulus of elasticity of steel and concrete respectively. Ie, Is and Ic are the equivalent moment of inertia, steel pipe inertia and concrete pipe coating inertia. The inertia can be approximated by Pi * R^3 * t R is the mean radius of the pipe or coating. Assume equivalent radius is same as steel radius and solve for equivalent thickness. You can recompute equivalent radius and solve again for new thickness. Please note you may use 1/2 or so (cannot recall exact number as neutral axis will move) of the concrete inertia as it will crack in tension. AutoPipe will give you stress in the equivalent steel pipe. You may need to evaluate the stress at most stress point by splitting the moment between pipe and coating proportional to their E*I. For example Ms = M * EsIs/EsIe and Mc = M* EcIc/EsIe And calculate stress for pipe and concrete using their actual diameter,thickness and material. So in conclusion, of modeling a concrete encased steel pipe, based on the information above: 1. Insert a pipe property 2. Combined Concrete / Steel Stiffness: a. Set Pipe material = Ns (nonstandard) b. Calculate / insert the pipe properties for the combined Concrete / Steel Pipe 3. Account for weight and correct size: a. Set insulation thickness = XXX inches b. Set Insulation material = Other c. Set Insulation density = XXX lbs/cuft ( for concrete only). d. Set Density = XXX lbs/cuft ( for steel only) Note: setting the correct insulation thickness, insulation density, and pipe density will accurately account for the weight and outside dia of the combined pipe/ concrete for the wind / wave / current loading. 4. Because the material is set to NS, update the data on the Press / Temp/ PipeID tab. a. Calculate and insert the expansion coeff, hot mod, and hot allowable based on the combined concrete / steel pipe. Notes: 1. Take care not to double up on insulation/lining density and pipe density 2. Similar approach may be used here to come up with an equivalent modulus for the modeling pipe with Fins: . However, additional pipe properties must be changed to account for the fin weight and added area affected by the wind. Recommend using Insulation settings, but be careful with the correct equivalency calculation. #2. Corroded PIpe or Spot corrosion?: Question: Does AutoPIPE offer a function or upgrade that will analyze corroded pipe with the following user information: a. Corrosion network sizes b. Longitudinal and rotational positions c. Minimum wall thickness at pit depths Answer: The following enhancement has been logged : CAE-CR-10121 , Add ASME B31G: Remaining Strength of Corroded pipeline. #3. Corrugated Straight pipe There are 3 options to choose from: A. Apply a special pipe id to the length of corrugated piping changing that pipe id's Pipe material to NS (NonStandard), update pipe properties using equivalent stiffness values in Long Modulus, Hoop Modulus, and shear Modulus; adjusting other pipe properties as needed. B. Place back to back Flexible joints over the length of straight pipe using the correct stiffness values. C. Insert back to back bends over the length of straight pipe, for example 10/1000 angle at each bend, but ending with straight end connections. In the model input grid change the bend's Flexibility Factor from Automatic to the correct value. Note: there has been no official testing done using option C, but appears to work in theory #4 Jacketed Piping Please see the following AutoPIPE help section: Help Contents Contents Tab Modeling Approaches Modeling Approaches Pipes Jacketed Pipe First create the carrier pipe with locations of all spider supports along the inside of the jacket piping. Then easily create the Jacket by using the graphical Select and Copy / Paste functions. Select the range of carrier pipe including valves, flanges, reducers etc and paste the coped selection with a small offset ( remember - no 2 node points should be in the exact same point, small offset). This modeling technique is covered in advanced training. Notes : a. Carrier pipe and jacket modeled as two separate segments with different pipe identifiers e.g. Jacket6 and carrier8 b. Segments may be made of different materials and have different operating conditions c. Carrier pipe is supported by the jacket at regular intervals using spacers (spider support) and at flanged ends. d. Spacers are modeled as two point supports e.g. guide between a carrier segment point and a jacket segment point. e. If both Carrier and Jacket are filled with the a fluid the analysis would be double counting weight of contents for both pipes if both the SG for the Carrier Pipe and Jacket Pipe were entered. Modeling Approach: 1. Create a new PipeID for the section of Carrier pipe that is inside of the Jacket piping 2. Set this new Carrier PipeID SG = 1.00 (assuming water filled pipe). 3. Insert a new PipeID for the section of Jacket pipe covering the Carrier piping. 4.Set this Jacket PipeID SG to an equivalent SG = weight of liquid from Jacket Pipe ID volume - Carrier Pipe OD volume This approach accurately accounts for the weight of fluid for both pipes. f. Remember to only apply hydrodynamic (e.g. submerged piping), wind, and insulation only to jacket. g. Ideally suited for graphical copy/paste operations h. New segment cannot be inserted at the start of a 2 point component like a valve. New segment at end of the valve is ok therefore need to insert small run point before the valve to connect the jacket segment. i. Be sure to check any interference between inner and outer jacket. AutoPIPE does not perform clash detection. Recommend export model to Bentley Navigator. j. Consider taking an official AutoPIPE training class, this is covered in the class with extra documentation. i. For underground jacketed pipe, apply soil properties to the Jacket (outside) pipe only, the carrier pipe inside of the jacket is supported by spacers, not soil. Again, confirm soil properties are only applied to the outside pipe for the length of jacketed piping underground. k. Recommend setting pipe graphics to be transparent, View Transparency toggle the check box ON for Pipe, and press OK button. View model is solid model view, similar to screen shot above. L. Model multiple carrier pipes using the same technique as shown above, connecting all carrier pipe supports to the same node point on the jacketed pipe. #5 Large Bore Piping: Question: Are there any problems analyzing big diameter pipe systems? It was indicated that some issues with regards to Caesar's analysis of big diameter pipe analysis? Answer: This is a long standing issue with the Piping codes and this question comes up often. Basically the piping codes only supports SIF calculations for D/t 100, hence large diameter pipes fall outside this limit. Caesar prints a warning when this occurs and AutoPIPE will be doing the same in v9.1. We recommend for users to perform a local stress analysis (i.e. FEA) at these connections to determine a more accurate SIF and flexibility factors to enter back into the Pipestress model. Note: Some WRC standards are also available to calculate SIF's e.g. for Trunnion elbows #6. Can AutoPIPE handle 12 to 30 foot diameter welded steel pipes with internal veins? Mostly for steam flow… Answer: Yes, AutoPIPE can be trusted to model large diameter piping systems as long as it does not exceed the code requirements. However, when D/T 100, AutoPIPE can be used to provide the correct forces, moments, and displacements in the piping system by applying these user-defined SIF and flexibility factors. Care should be taken with such systems as they are susceptible to ovaling and denting and that should be considered while lifting or supporting the pipes. Modeling, an equivalent pipe section with same section modulus for this large pipe with stiffeners could be calculated. Then adjust the density of pipe to get the equivalent weight of stiffened pipe when selecting a non-standard material (NS). #7. Rigid Pipe Element with "ZERO" Mass (Pipe & Water S.G.=0) Answer: Select a range of pipe, press Insert Rigid options over Range uncheck "Include Weight" and user choice to consider "Include Thermal Expansion". #8. Pipe Lining: Question: what is the best way to model material on the ID of pipes. Answer : The cladding mentioned in the pipe properties grid is referring to application on the outer most diameter of insulation. On the pipe properties dialog, enter as lining thickness. Please note that lining is an added weight only and would not contribute the pipe stiffness. If this lining increases the stiffness, then a modified pipe modulus may be entered by computing an equivalent modulus that would give that same EI Ee*Is=Es*Is+Ec*Ic This will give correct bending stiffness by using Ee instead of Es in AutoPIPE. Axial stiffness will be approximate. s=steel, c=CRA. Is=steel moment of inertia. #9. How to model NFPA pipe? Does AutoPIPE have Fire Protection Requirement capabilities? Answer: NFPA (National Fire Protection Association) codes provide specific details about design, construction, operation, and maintenance of piping systems for fire protection. To answer these questions, at this point AutoPIPE does not have a specific NFPA piping code. However, NFPA codes typically refers to the appropriate ASME design code which AutoPIPE may already have. Please review your NFPA code for stress analysis requirements. If AutoPIPE was found to contain the correct Piping Code specified by NFPA, then model the piping system in AutoPIPE as required. #10. Can you analyze tubing, i.e. small dia [ex. 1/2" (13mm)]? Answer: Yes, AutoPIPE has been used in development of tubing systems by our many users. From the AutoPIPE online help: Standard Pipe Cross Sections - ANSI/ASME Library. This library of pipe cross sections pertains to the ANSI/ASME codes B36.10M and B36.19M (1985). They are contained in the file AUTOPIPE.LIB. Pipe sizes from 1/8 (.405") OD with 0.049" wall thk, up to 36" sch 40 wall thk. Copper Tubing Type L (ASTM B88 Refrigeration piping), pipe sizes from 1/4 (.375") OD with 0.030" wall thk up to 3" (3.125") OD with 0.090" wall thk #11. My pipe size and material is not available in AutoPIPE libraries. What options do I have? Answer: A. Pipe size options: AutoPIPE can model almost any size pipe used in most typical piping system built today. for a complete list of pipe sizes available in AutoPIPE, please see the following AutoPIPE help section: Help Contents Contents Tab Reference Information Libraries Standard Pipe Cross Sections 1. If you need to specify a pipe that is not currently in the library, perform the following: open the pipe properties dialog screen in a model, place cursor in the "Nominal Diameter" field and press F1 keyboard key. This will display the help for this field, there are instructions on how to enter in your Non-Standard (NS) pipe size. 2. If you like the pipe size added to a customize library file, please log a service ticket requesting information about creating a Component Library file. B. Pipe Material options: select this link for information to address this issue #12. How can I model a pipe that is supported over its all length on an open trench or gutter Answer: From AtuoPIPE Forum: I am assuming from open trench or gutter, you mean the pipe is only supported at its base, or is only semi-embedded. The response below is based on this assumption. This is one of the planned features for AutoPIPE to provide the user with functionality to be able to define friction properties (Horizontal and longitudinal) for a pipe resting on ground. For an alternate workflow, the following options may be considered: Option 1: The Buried pipe option can be used to model semi-embedded (debris builds up on the sides of the pipe over time) or non-embedded piping. The difficulty is calculating a transverse horizontal (lateral) and longitudinal soil stiffness. a) The vertical up soil stiffness K1, P1 and K2 can be taken as 0. b) The transverse horizontal K1 and P1 is usually taken as low values. Higher if semi-embedded pipe is anticipated. c) Transverse vertical down K1 and p1 can be calculated as non-zero with H=0 d) The longitudinal K1 and P1 would go to zero with Z=0 but there may be an alternative equation in some textbook which would calculate a non-zero longitudinal K1 and P1 although I suspect it would be a low value since only line contact of soil with the pipe is assumed. You may wish to enter some non-zero K1 and P1 values to evaluate the longitudinal frictional stiffness effect back on the pipe system. It is recommend to set all final stiffness, K2 = 0.1 lb/in/ft (0.006Kg/m/mm) to avoid convergence problems. Option #2 An alternative may be to provide V-stop supports with a friction coefficient defined. See Also Bentley AutoPIPE External Links Bentley Technical Support KnowledgeBase Bentley LEARN Server Comments or Corrections? Bentley's Technical Support Group requests that you please submit any comments you have on this Wiki article to the "Comments" area below. THANK YOU! You may find some interesting scenarios on our Pipe Stress Wiki: https://communities.bentley.com/products/pipe_stress_analysis/w/pipe_stress_analysis__wiki/8058.model-different-types-of-piping-in-autopipe.aspx The example scenarios have information on how to calculate the equivalent modulus for say pipe enclosed in concrete or pipe with lining that increases stiffness of the pipe. Similar approach may be used here to come up with an equivalent modulus for the pipe.
↧