Anode assembly with reduced attenuation properties for cathodic protection systems

Abstract

An anode assembly is disclosed for use in a cathodic protection system. The anode assembly includes an elongated housing, an electrical cable, an anode, and electrically conductive backfill. The housing has a leading end and a trailing end through which the electrical cable extends. The anode is located within the housing and is in the form of a plurality of electrically conductive segments which are spaced apart from each other and which are electrically connected to the electrical cable at respective electrically conductive joints. The backfill surrounds the anode and cable within the housing.

Claims

1. An anode assembly for use in a cathodic protection system, said anode assembly having a leading end and a trailing end and comprising: a) a continuous electrical cable extending the length of said anode assembly between said leading end and said trailing end, said continuous electrical cable having an electrically insulating covering thereon, said electrically insulating covering having at least first, second, third and fourth sequentially spaced openings therein, whereupon each of said openings exposes a respective sequential portion of said electrical cable thereat, said continuous electrical cable comprises at least one electrically conductive wire, wherein a first electrically conductive anode segment is electrically connected in parallel across said first and second sequentially spaced openings by respective first and second electrically conductive joints, and wherein a second electrically conductive anode segment is electrically connected in parallel across said third and fourth sequentially spaced openings by respective third and fourth electrically conductive joints, and wherein each of said electrically conductive joints comprises a body of electrically insulating material molded in situ about said electrically conductive joint so that it completely covers and encapsulates said electrically conductive joint and is integrally bonded directly to portions of said electrically insulated covering; b) an anode comprising at least said first electrically conductive anode segment and said second electrically conductive anode segment, said first electrically conductive anode segment being electrically connected in parallel across said first and second sequentially spaced openings, said second electrically conductive anode segment being electrically connected in parallel across said third and fourth sequentially spaced openings; and c) an elongated housing, said continuous electrical cable extending through said housing between said leading end and said trailing end, said anode extending along said electrical cable within said housing, said elongated housing being filled with an electrically conductive backfill, said conductive cable being surrounded by said electrically conductive backfill, said first electrically conductive anode segment being spaced from said second electrically conductive anode segment by a gap but being electrically interconnected to each other indirectly by a portion of said continuous electrical cable extending between said second and said third sequentially spaced openings.

2. An anode assembly for use in a cathodic protection system, said anode assembly having a leading end and a trailing end and comprising: a) a continuous electrical cable extending the length of said anode assembly between said leading end and said trailing end, said continuous electrical cable having an electrically insulating covering thereon, said electrically insulating covering having at least first, second, third and fourth sequentially spaced openings therein, whereupon each of said openings exposes a respective sequential portion of said electrical cable thereat; b) an anode comprising at least a first electrically conductive anode segments and a second electrically conductive anode segment, said first electrically conductive anode segment being electrically connected in parallel across said first and second sequentially spaced openings, said second electrically conductive anode segment being electrically connected in parallel across said third and fourth sequentially spaced openings; and c) an elongated housing, said continuous electrical cable extending through said housing between said leading end and said trailing end, said anode extending along said electrical cable within said housing, said elongated housing being filled with an electrically conductive backfill, said electrically conductive cable being surrounded by said electrically conductive backfill.

Description

DESCRIPTION OF THE DRAWING

(1) FIG. 1 is a side elevation illustration of a prior art linear anode assembly for use in a cathodic corrosion protection system; and

(2) FIG. 2 is a side elevation illustration of an anode assembly constructed in accordance with the subject invention for use in a cathodic corrosion protection system.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(3) Referring now to the various figures of the drawing wherein like reference characters refer to like parts, there is shown at 120 in FIG. 2 one exemplary embodiment of a linear anode assembly constructed in accordance with the subject invention. The anode assembly 120 is similar to a SPL-FBR anode assembly 20 (FIG. 1) available from Matcor, Inc., the assignee of the subject application, except for the construction and arrangement of its anode (which will be described shortly).

(4) The details of the prior art SPL-FBR anode assembly are shown in FIG. 1. Thus, as can be seen that prior art anode assembly 20 basically comprises an anode 22, an internally insulated electrical conductor or cable 24, a porous outer fabric or cloth housing 26, an electrically conductive, e.g., coke, backfill 28, and external braiding 30 which provides additional support for the housing. The anode assembly 20 can be of any length, from 10 feet to lengths of more than 1,000 feet.

(5) The cable 24 is of any conventional construction, e.g., it comprises a plurality of electrically conductive, copper strands or filaments having an electrically insulating covering or coating 34, e.g., KYNAR® polyvinylidene fluoride, thereon. The cable is centered in the housing and extends therethrough so that one portion 36 extends outside of the trailing end 20A of the anode assembly, while an opposite portion 38 extends out of the leading end 20B of the anode assembly.

(6) The anode 22 is formed of elongated thin flexible member, e.g., a wire, a ribbon, a tube, etc., which is electrically conductive, e.g., is a noble metal combination, such as a mixed metal oxide (MMO) over titanium or platinum over niobium/copper, or any other conventional anode material(s). The anode 22 is continuous in that it extends along the cable 24 virtually the entire length of the cable within the housing and is electrically connected to the cable at plural equidistantly spaced locations therealong. Thus, the anode 22 comprises plural segments 40, with each segment having a trailing end and a leading end which are electrically connected to respective portions of the electrical conductor(s) of the cable 24. The anode assembly 20 can include any number of anode segments, depending upon the length of the anode assembly. The trailing end of the first anode segment 40A is electrically connected to the conductor(s) of the cable 24 at a first connection 24A which is located adjacent the trailing end of the anode assembly. The leading end of the first anode segment 40A is electrically connected to the conductor(s) of the cable 24 at a second connection 24B. The second connection 24B is located at a predetermined distance, e.g. X meters, from the first connection 24A. The trailing end of the next successive anode segment 40B is also electrically connected to the conductor(s) of the cable 24 at the connection 24B. The leading end of the anode segment 40B is electrically connected to the conductor(s) of the cable 24 at a third connection 24C which is located a predetermined distance, e.g., X meters, from the connection 24B. Successive segments are connected to the cable 24 in the same manner, with the leading end of the last segment 40N, i.e., the segment located closest to the leading end of the anode assembly being connected to the cable at a connection 24N located adjacent the leading end of the housing. Thus, the anode segments 140A-140N and the cable 24 run in parallel to each other through the fabric housing 26, with the backfill 28 surrounding them within the fabric housing.

(7) The integrity of each anode-to-wire (cable) electrical connection 24A-24N is critical and is preferably achieved by means of a KYNEX® connection. The KYNEX® connection is the subject of U.S. Pat. No. 8,502,074 (Schutt), which is also assigned to Matcor, Inc. and whose disclosure is incorporated by reference herein. Each connection 24A-24N basically comprises a first open region at which the anode segment is electrically connected to the elongated electrical conductor to form a good electrically conductive joint and a body of an electrically insulating material 32. The body of electrically insulating material 32 is molded in situ about the joint so that it completely covers and encapsulates the joint and is integrally bonded directly to portions of the electrically insulation on the cable contiguous with the open region. This arrangement electrically insulates the joint and prevents the ingress of water or other materials into the joint.

(8) It should be pointed out that the KYNEX® connection is not the only way that anode segments are connect to the cable of a linear anode assembly. Thus, other manufacturers of linear anodes make use of other types of connections, e.g., a mechanical connection in conjunction with a heat shrink tube to encapsulate the connection point (the electrical joint).

(9) Irrespective of the type of connection used between the anode 22 and the cable 24 at the various connection points therealong, prior art linear anodes are susceptible to the attenuation problem described above.

(10) In contradistinction, the anode assembly 120 of this invention overcomes that problem by eliminating the continuous (albeit segmented) wire anode element and replacing it with an anode whose segments are spaced apart from each other. This “stitch” approach, while not visible from the exterior of the anode assembly, enhances the anode's performance in a corrosion protection system. In particular, by spacing the anode segments out along the entire assembly (versus one effectively “continuous” internal anode like the SPL-FBR anode assembly) the subject anode assembly permits one to power longer lengths of anode from a single location with a given DC power supply inasmuch as the attenuation would be significantly reduced. Thus, users of the anode assembly of this invention are able to run longer lengths of anode from a fixed source of power.

(11) The anode assembly 120 is shown in FIG. 2 and basically comprises an SPL-FBR anode assembly with a modified anode. In the interest of brevity the common features of the anode assemblies 120 and 20 will be given the same reference numbers and the details of the construction, arrangement and operation of those features will not be reiterated. Thus, as can be seen in FIG. 2 the anode assembly 120 basically comprises an anode 122, an internally insulated electrical conductor or cable 24, a porous outer fabric or cloth housing 26, an electrically conductive backfill 28, and external braiding 30. The anode assembly 120 can be of any length, from 10 feet to lengths of more than 1,000 feet, but is particularly useful when provided in long lengths due to its resistance to attenuation loss at greater lengths than conventional linear anode assemblies (e.g., the SPL-FBR anode assembly of Matcor, Inc. and anode assemblies from other manufacturers).

(12) The anode 122 is formed of elongated thin flexible member, e.g., a wire, a ribbon, a tube, etc., which is electrically conductive, like that of the anode 22. The anode 122 extends along the cable 24 within the housing and is connected to the conductor(s) of the cable at equidistantly located points therealong. However, unlike the anode 22 it is not continuous, i.e., it includes segments 140 which are separated from each other. Each segment has a trailing end and a leading end which are electrically connected to respective portions of the electrical conductor(s) of the cable. The anode assembly can include any number of anode segments, depending upon the length of the anode assembly.

(13) As can be seen in FIG. 2, the trailing end of the first anode segment 140A is electrically connected to the conductor(s) of the cable 24 at a first connection 124A which is located adjacent the trailing end of the anode assembly 120. The leading end of the first anode segment 140A is electrically connected to the conductor(s) of the cable 24 at a second connection 124B. The second connection 124B is located at a predetermined distance, e.g. 3 meters, from the first connection 124A. Unlike the anode assembly 20, the trailing end of the next successive segment 140B of the anode 122 of the anode assembly 120 is not connected to the cable at the connection 124B. Rather it is connected to the conductor(s) of the cable 24 at a third connection 124C, which is located a predetermined distance, e.g., 6 or 9 meters, from the connection 124B. The leading end of the second anode segment 140B is electrically connected to the conductor(s) of the cable 24 at a fourth connection 124D. The fourth connection 124D is located at a predetermined distance, e.g. 3 meters, from the third connection 124C. Successive segments of the anode 122 are connected to the cable 24 in the same manner, with the leading end of the last segment 140N, i.e., the segment located closest to the leading end of the anode assembly being connected to the cable at a connection 124N located adjacent the leading end of the housing. Thus, the anode segments 140A-140N and the cable 24 run in parallel to each other through the fabric housing 26, with the backfill 28 surrounding them within the fabric housing, but with immediately adjacent segments being separated from each other by a gap.

(14) Like the anode assembly 20, each electrical connection 24A-24N of the anode assembly 120 is accomplished by means of a connection which is the subject of U.S. Pat. No. 8,502,074 (Schutt).

(15) As should be appreciated by those skilled in the art by segmenting the anode and extending the spacing between anode segments (versus one continuous internal anode) the subject anode assembly enables users to power longer lengths of anode from a single location as the attenuation would be significantly reduced. This allows users to run longer lengths of anode from a fixed source of power.

(16) It should be pointed out at this juncture that in the exemplary embodiment the length of each anode segment is described as being 3 meters. That is merely exemplary. Thus, the lengths of each anode segment can be another value, if desired. So too, the spacing or gap between the adjacent anode segments is described as being either 6 or 9 meters. Those values are also merely exemplary. Thus, the spacing or gap between successive anode segments can be another value, if desired.

(17) It should also be pointed out that other changes can be made in the anode assembly for other cathodic corrosion protection applications. Thus for example, the anode assembly can be constructed so that it does not include any fabric housing or other wrap. That variant anode assembly can be used in an application wherein the anode assembly is disposed within coke backfill in the ground or in an application wherein the anode is disposed directly within the ground without any coke backfill.

(18) Without further elaboration the foregoing will so fully illustrate our invention that others may, by applying current or future knowledge, adopt the same for use under various conditions of service.