Table of Contents

**NC 3658.3 provides a flange leakage evaluation method based on the NC code for flanges using high strength bolts. Caesar II software has a nice module in its input spreadsheet to use this method efficiently with ease. In the following paragraphs, I will describe the methods of flange leakage evaluation by NC 3658.3 method using Caesar II. **

**Criteria** for NC 3658.3 Method Application

**NC 3658.3 Method for flange leakage evaluation can only be applied if the following two conditions are met: **

**Flanges, bolts, and Gaskets used are designed based on as specified in ASME B 16.5a and****Bolting material must have an allowable stress value at 100°F(38°C) >=20000 psi (138 MPa) (High Strength Bolting)**

**Governing Equation**s as Per NC 3683.5 method

By NC 3658.3 method the generated external moment (Mfs) is limited to a value as provided by the below-mentioned equation:

### Mfs<=3125(Sy/36000)C X Ab (in U.S. Unit);

Here

- Sy=Yield strength of flange material at the temperature and
- Ab= Bolt area The ratio of Sy/36000 has to be taken less than unity.

So it is obvious from the above equation that we have to enter the bolt area and yield strength as input into Caesar II Spreadsheet.

## Flange **Evaluation steps followed in Caesar II**

- Select Flange Node (From/To/Both) and Calculation Type (NC-3658.3) as shown in Fig. 1.
- Input Bolt circle diameter from ASME B 16.5.
- Input Yield Strengths at the temperature from ASME BPVC code Section II Part D Table Y1.
- Calculate the Bolt Area (Ab) as shown below and input in required place:

Bolt area, Ab is the total cross-sectional area of the bolts at the root of thread or section of least diameter under stress.

## Bolt Area Calculation for NC method

**Calculate the bolt area as mentioned below **

### Droot = D1bsc – 2*0.21650635P & D1bsc = Dbsc – 2*h

Where

- Droot = Root diameter of the bolt
- Dbsc = Basic major (nominal) diameter of bolt (as per ASME B1.1, para 8.3)
- D1bsc = Basic Minor diameter (as per ASME B1.1, para 8.3)
- h = Height of thread (as per ASME B1.1, Table 5)
- P = Pitch of Bolt (as per ASME B1.1, Table 1)

### Root Area of bolt (Ab) = n x [(pi/4)* Droot* Droot)]

Where n = No. of bolts as per flange pressure rating class

- Now go to the Load Case Option Editor (Fig.2) and select flange analysis temperature based on operating/design conditions and click the Run button for analysis.

- Select the Load Case(s) for which Flange Leakage Check has to be performed and see the results. If the ratio of Flange Stresses to Allowable Stress is less than 100 % (See Fig. 2), Then the flange is within the allowable limit and should not produce leakage. If it is more than 100%, Then try to reduce moments at the flange by re-analysis of the system and recheck using the above method.

## Allowable Stress for NC 3658.3 method as per Caesar II

Caesar II Allows the user to check the NC flange leakage check at 9 temperature case conditions (operating condition ), Hydrotest, and Sustained condition at a time.

In CAESAR II, an Equivalent flange Stress S is calculated based on the following formulas, and then the calculated stress is compared to Sy (or 2*Sy for occasional load cases), in the following manner:

### S = 36,000* Mfs / (CAb * 3125) ≤ Min(Sy, 36000) (non-Occ)

### S = 36,000 * Mfd / (CAb * 3125) ≤ 2.0 * Min(Sy, 36000) (Occ)

**Note that both the above equation are in the FPS unit. For metric or other unit systems, the Caesar II software converts the 36,000 values in the above equations to the appropriate set of units.**

Few more related useful resources for you..

Guidelines for Selection of Various Types of Flanges

Methods for Checking Flange Leakage

Flange Insulating Gasket Kits for Industrial Application

Recorded Webinar on Detailed Flange Analysis with CAESAR II using EN-1591

Pressure Temperature Rating and Flange rating of ASME Flanges

Methods for flange leakage checking by Pressure Equivalent Method using Caesar II

PROCEDURE FOR FLANGE-BOLT TIGHTENING OF VARIOUS SIZES OF FLANGES

Flange Leakage Evaluation based on NC 3658.3 Method method using Caesar II

Few points on Gaskets for leak Proof Flanged joints

Consideration of Flanged Bend while modeling in Caesar II

Flange Leakage checking in Caesar II using ASME Section VIII method

Functions of Gaskets for leak-proof Flanged joints

is flange leakage done for cold piping ?

Yes..for both cold piping and hot piping flange leakage need to be performed..

What is the criteria for flange leakage of cold lines?

Criteria should be based on ITB document..I dont feel it will defer from hot lines…In short you can check/ investigate for leakage possibilities in the following cases:

1. On control valves

2. On PSv connections

3. On other connections where leakage can cause serious harm to mankind

Roughly you can check all locations where bending stress near to flanges are more than 4000 psi.

Dear Anup,

Kindly share your whatsup number for asking more Stress related questions?

Guys, I am creating Whatsup Group for Stress Analysis member ?

Please share your phone number to my what’s up number +91-99678-12330

hello sir in flange leakage evaluation method NC 3658.3 in result if ratio is more than 100% how to change the moments explain in detail

regards

rizhwan md

Hi all,

This site has been so helpful, word cannot express my gratitude to the facilitator for a job well done.

Thanks alot

Dear Sir,

I come from the middle east region which is not a very seismic prone zone. I am performing flange leakage using the NC method. I wanted to enquire if flange leakage needed to be performed for the wind and seismic cases as well??

Flange leakage is normally not checked for wind and seismic cases. However if your client says to do so you don’t have other option.

Hi Good Evening Every Body,

I have Query Regarding NC 3658.3 Result, I notice that in some cases when i am checking flange leakage for higher flange size in output of flange leakage area of bolt (AB sq mm) is showing ***** Value in SI units. if you run same file in US unit than AB sq Inch value is there. so My Query is why it happen.