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Sacrificial anode protection circuit resistance

The basic design of sacrificial CP system includes calculation of cathodic protection circuit resistance, potential difference between the anode and structure, anode output, number of anodes, and the anode life expectancy. A schematic of the cathodic protection test is given in Fig. 15.11. To estimate current requirements, a test is needed to determine the current i ) necessary to provide adequate protection for the pipeline. This can be done by applying current using a temporary test setup and adjusting the current from the rectifier until the cathodic protection criteria is reached. [Pg.624]

Backfill the soil replaced over the pipe in the trench (general connotation). In cathodic protection, special backfills are packed around the anodes. These backfills are selected to lower circuit resistance of the anode for sacrificial anodes a gypsum/bentonite mixture is used, and for impressed-current anodes, coke breeze. [Pg.1375]

Figure 8.16 shows an equivalent electrical circuit that simulates the pipeline cathodic protection depicted in Figure 8.9. Both pipeline and sacrificial anode (galvanic anode or inert anode) are buried in the soil of uniform resistivity. The pipehne is connected to the negative terminal and the anode to the positive terminal of an external power source (battery). The arrows in Figure 8.16 indicates the direction of the ciurent flow from the anode to the pipehne. The electron flow is also toward the pipehne to support local cathodic reactions and the protechve current (Ip) flows from the pipehne to the power supply. The soil becomes the electrolyte for complehng the protective electrochemical system or cathodic protechon circmt [24]. Figure 8.16 shows an equivalent electrical circuit that simulates the pipeline cathodic protection depicted in Figure 8.9. Both pipeline and sacrificial anode (galvanic anode or inert anode) are buried in the soil of uniform resistivity. The pipehne is connected to the negative terminal and the anode to the positive terminal of an external power source (battery). The arrows in Figure 8.16 indicates the direction of the ciurent flow from the anode to the pipehne. The electron flow is also toward the pipehne to support local cathodic reactions and the protechve current (Ip) flows from the pipehne to the power supply. The soil becomes the electrolyte for complehng the protective electrochemical system or cathodic protechon circmt [24].
Sacrificial anodes can be installed as single anodes or in groups. In practice, sacrificial anodes are placed relatively close to the cathode (protected structure) to decrease the resistance of the electric circuit. In water, low potential sacrificial anodes can be mounted directly (through an insulation washer) on the protected surface, while it is better to place high potential sacrificial anodes on appropriate supports at some distance (e.g., 0.6 m) from the cathode, which has an advantageous effect on the potential distribution. In soil, the method of sacrificial anode installation depends on many local factors, e.g.,... [Pg.429]

See other pages where Sacrificial anode protection circuit resistance is mentioned: [Pg.170]    [Pg.245]    [Pg.784]    [Pg.254]    [Pg.426]    [Pg.349]    [Pg.445]    [Pg.888]   
See also in sourсe #XX -- [ Pg.624 , Pg.626 ]



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