CATHODIC PROTECTION CALCULATION

1 PROJECT: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING: Owner Job No.: Type : CAL Contract Job No.: Page A CATHODIC PROTECTION CALCULATION PROJECT: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING: Owner Job No.: Type : CAL Contract Job No.: Page B 1 2 3 4 5 6 1 2 3 4 5 6 1 2 3 4 5 6 A X B X 1 X 2 X 3 X 4 X 5 X 6 X 7 X 8 X

2 6 5 4 3 2 1 Rev Data Prepared By Checked By Approved By Status Document Revision PAGE REV. PAGE REV. PAGE REV. PROJECT: Client: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING : Document No.: Rev.: 1 Owner Job No.: Type : CAL Contract Job No.: Page 1 of 8 I N D E X 1 .INTRODUCTION 2 .CURRENT REQUIREMENTS 3. GROUND BED (GB) DESIGN 4. TRANSFORM ER/RECTIFIER SIZING 5. CURRENT SPREAD 6. PROJECT EXECUTE PROJECT: Client: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING : Document No.

3 : Rev.: 1 Owner Job No.: Type : CAL Contract Job No.: Page 2 of 8 1. 0 BINTRODUCTION The CATHODIC PROTECTION system has been designed to protect the underground pipe Codes and Standards All the design and installation for CATHODIC PROTECTION syst em shall be in accordance with the latest edition of NACE standards (NACE RP 01-69). For materials and equipment, IEC code shall be considered. Design Condition The permissible maximum pipe to soil potential shall be V (with referenc e electrode Cu/CuSoR4R), V is applied for the prot ection of both carbon steel and zinc coating.

4 Design condition include: Design Soil Temperature 30 C Soil resistivity 3000-5000 Ohm-cm Period of Operation 20 years Backfill Coke Breeze or Graphite Powder Anode High Silicon Cast Iron Cable Non-Armoured XLPE/PVC or PVC/PVC 2. 4 BCURRENT REQUIREMENTS For each prot ective item(s) a DC feeder, required current shall be calculated as follows: SdII*= [Eq. 1] W here: I = Required PROTECTION current (mA); dI = PROTECTION current density (mA/mP2P); S = Surface of item to be protected (mP2P). As a consequence of above CALCULATION results, number of DC feeders and their rating shall be selected.

5 DC feeder output current shall be suitably over-sized in order to allow spare current. PROJECT: Client: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING : Document No.: Rev.: 1 Owner Job No.: Type : CAL Contract Job No.: Page 3 of 8 5 BProtection current density Considering design life, soil nature and applied coating types, PROTECTION current density values (dI) for design purposes are listed in Table 1. Table 1 PROTECTION current density (dI) According to NACE RP-01-76 Item Anticorrosion Coating Current Density (dI) Steel piping Poorly Coated Steel in Soil or Water 1 mA/mP2 Steel piping Well Coated Steel in Soil or W ater mA/mP2 Steel piping Very Well Coated Steel in Soil or Water mA/mP2 Por Less Underground piping Piping to be prot ected are Fire water (FW ) pipes, Potable water (PW ) pipes, Cooling water (CW) pipes and Sanitary drain pipes (SD).

6 Characteristics of these lines have been extracted from piping department. 3. 1 BGROUND BED (GB) DESIGN The positive ground bed system consists of a remote horizontal anode system. The design of GB shall be for maximum output current and for a 20 years period. To obtain minimum no. of anodes in each GB, three cases shall be calculated and maximum of those shall be selected. Resistance Rv: Resist ance of Vertical Anode to Earth, Ra: Internal Anode Resist ance, Rvn: Resistanc e to earth for n Vertical Anodes in Parallel, Rca: Anode Cable Tail Resistanc e, Rg: Ground Bed Resistanc e, Rc: Cable Resist ance from Power Source to First Anode, Rcp: Coat ed Pipe Resist ance.

7 RRTotalR: Total Resist ance PROJECT: Client: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING : Document No.: Rev.: 1 Owner Job No.: Type : CAL Contract Job No.: Page 4 of 8 RRhnR: Resistance to Earth for Horizont al Anodes in Parallel RRPotR: Resistance of Pot entiometer R p/s: Resist ance of pipe to soil Furthermore each ground bed shall be sized in respect of the maximum resist ance (Rmax) of the relevant circuit, which is defined as the ratio between maximum output volt age and maximum output current of each DC feeder.

8 The resistance of each circuit comprises ground bed to soil resist ance, negative and positive circuits cables resist ance. Ground bed resistance Single vertically laid anode resistance shall be calculated as follows (Dwight s formula): ++=1* * [Eq. 2] W here: : Soil resistivity ( * Cm); L: Anode length (feet); d: Anode diameter (feet). Total n anode (constituted by two or more vertically laid anodes) resist ance shall be c alculated as follows: () + +=NagLdLNaLNaRaRvn* **21* ** [Eq. 3] W here: Na: Number of anodes g: Spacing between anodes (feet) Ground bed resist ance (constituted by one or more ground bed ) shall be calculated as follows (as measurable at Positive Bond Box): RvniRgni111 == [Eq.]

9 4] Total resistanc e for CPS shall be calculated as follows: sRpRcRRgTotal/++=+ RRPotR [Eq. 5] PROJECT: Client: TITLE: CATHODIC PROTECTION CALCULATION REVIEWED & EXECUTED BY : ENGINEERING : Document No.: Rev.: 1 Owner Job No.: Type : CAL Contract Job No.: Page 5 of 8 9 BNo. Of Anodes No. of vertical anodes for a CPS shall be calculated (with the iteration methods) as follows: + +=NagLdLLRaRvNna* **21* ** *1 [Eq. 6] W here Rvn is the max permissible resistanc e of (2 Ohm for horizontal anode equal t o Ohm for vertical anode).

10 Because there is not any formula for multi horizontal anodes, first we shall calculat e tot al resistance for vertical anodes and then convert it to horizontal anodes After calculating number of anodes, final resist ance shall be calculated with using [Eq. 3,4,5]. 10 BCurrent capacity Na=I/is W here: is : Maximum allowed current for one anode Consumption ratio Na=(cr*t*I)/(m*f) W here: cr: consumption rate for one anode t: total year m: anode weight f: utilization factor 4. 2 BTRANSFORMER / RECTIFIER SIZING The magnitude of DC voltage required in the output of each TR/REC is product of the maximum current capacity and the total circuit resistance, thus: VRDCR = I * Rtotal [Eq.]