CA2178511C - Resistored sacrificial anode assembly for metal tank - Google Patents
Resistored sacrificial anode assembly for metal tank Download PDFInfo
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- CA2178511C CA2178511C CA002178511A CA2178511A CA2178511C CA 2178511 C CA2178511 C CA 2178511C CA 002178511 A CA002178511 A CA 002178511A CA 2178511 A CA2178511 A CA 2178511A CA 2178511 C CA2178511 C CA 2178511C
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Abstract
A sacrificial anode assembly is insertable into a metal water storage tank to inhibit corrosion thereof and includes a cylindrical metal anode member having an end retained within a cylindrical plastic insulating sleeve which, in turn, is captively retained within a metal cap portion of the assembly. To regulate the amount of electrical current generated by the assembly during use thereof, a barrel-shaped resistor is supported within the assembly and interconnected between its anode and cap portions. The insulating sleeve has a generally U-shaped groove formed in a closed end thereof, with one leg of the groove extending diametrically across a central opening in the sleeve end that receives a core wire portion of the anode member, and the other groove leg extending generally chordwise relative to the sleeve end. The resistor body is received within the chordwise groove leg, and a lead wire of the resistor is extended through the curved and diametrically extending groove portions and spot welded to the core wire portion received in the central sleeve end opening. The configuration of the groove and the relative orientation of the resistor and sleeve opening causes the bent lead wire to form a resilient connection between the spot weld and the resistor body, thereby substantially reducing vibrational fatigue stress on the spot weld during shipping and handling of a tank having the anode assembly operatively installed thereon.
Description
` 217~5~ -Docket No .: RHWH- 0 0 1 9 RESISTORED SACRIFICIAL ANODE: A~ ~ PMRT-Y FOR M13TA1 TANK
RACT~I'.RI I OF T~E INVE NTION
The present invention relates generally to anode devices used to inhibit corrosion in metal water heater tanks and other metal 5 liquid storage vessels and, in a preferred embodiment thereof, more particularly relates to a specially designed resistored anode assembly useful in this corrosion-inhibiting application.
Conventional metal water heater tanks, like other types oE
metal vessels used to store liquids, are subject to corrosion 10 durin~ use. To inhibit this corrosion, sacrificial anodes, normally constructed of magnesium, aluminum or zinc, are inserted into the tank. The sacrificial anode is slowly cu.~ during the corrosion protection process while generating an electrical current. As the anode is slowly depleted, it~: simultaneously 15 generated electrical current cathodically protects the ~ank against corrosion .
The service life of the anode tends to be inversely dependent upon the amount of electrical current it generates in cathodically protecting the tank. In many fresh water supplies, particularly 20 those having a hLgh mineral content, the current flow generated by the anode ls relatively high, resulting in a corresponding decrease in the useful life of the anode. In order to control the rate of uc,~ u.~.~Lion of a sacrificial anode, various anode ~ u~Lions ~ 2178511 have been proposed in which a resistor is inuuL~ ted in the anode, and electrically connected between the anode and its protected tank, to automatically regulate the electrlcal ourrent generated by the anode during its operation and thereby increa~;e 5 the 6ervice lif e of the anode .
While these resistored anode devices typically extended anode life, many of them also tended to be of a relativ~ely complex construction, rather difficult to assemble, and relatively expensLve to fabricate.
Many of these problems are essentially eliminated by a prior art sacrificial anode assembly that in~.L~o-~es, in a simplified manner, an ordinary barrel-type carbon resistor into the interior of the assembly. This prior art anode assembly include6 a cylindrlcal plastic insulating sleeve captively retained within the metal cap portion of the anode assembly and having a closed end with a central opening through which an end portion of the metal anode body core rod extends. A diametrically extending groove, which intersects the central sleeve opening~ is formed in the closed sleeve end.
The cylindrical resistor body is disposed in a radial portion of the sleeve end groove, with one of the resis~or end leads being radially extended over the anode rod end and soldered thereto. The other resistor end lead passes through an axially extending exterior side surface groove in the insulating sleeve and is soldered at its outer end to an external metal cap portion of the anode assembly.
- ~ 2~
Although this method of operatively positioning a resistor in a sacrif icial anode assembly provides a worthwhile reduction in assembly time and cost, and provides the desired regulation of anode current generation, it has been found that it can create a problem relating to the tjL~u~:LuLal integrity of the completed anode assembly. Specifically, it has been found that in certain shipping orientations of the tank in which the anode assembly L8 installed, harmonic vibrations may be created within the central anode core rod which are transmitted to the solder ~oint connectillg a resistor end lead to the rod. These vibrations can fatigue and break the rod/lead solder ~oint, thereby rendering the anode assembly inoperative . .
From the foregoing it can be seen that it would be desirable to provide a sacrificial anode assembly, of the type having an insuiating sleeve-installed resistor as generally described above, which substantially eliminates this vibration-caused solder ~oint breakage problem. It is accordingly an ob~ect of the present invention to provide such a sacrificial anode assembly.
SUM~ARY OF THE lrlV~nlll In carrying out principles of the present invention, in accordance with a preferred ~ L thereof, a specially designed resistored sacrificial anode assembly is provided for use in a metal liquid storage to inhibit vessel corrosion The anode assembly may be secured to the vessel, to extend into its liquid filled interior, and ~ ncll~A~ an elongated metal anode member having a core wire extending longitl~in~l~y . .
` ~ 21~85~1 therethrough and pro~ecting outwardly through an end thereof. An insulating sleeve mem~er, preferably formed from a molded plastic material, receives and is captively retained on this anode member end and has an ond wall portlon with a central opening therein that 5 receives an end portion of the core wire. A hollcw metal cap member received and is captively retained on the insulatLng sleeve member .
An electrical resistor is ~ po~d within the cap member and has a cylindrical body portion with first and Gecond ends. First 10 and second electrical lead wires respectively extend outwardly from the first and second resistor body ends.
Exterior surface groove means are formed in the end wall portion of the insulating sleeve member and receive the resistor body in a manner positioning its length perpendicular to the 15 longftudinal axis of the insulating sleeve. These groove means have a curved portion through which the first electrical lead wire extends to the core wire end portion, the groove means being configured to permit lateral ~. t of the first electrical lead wire therein. Means, representatively in the form of a spot weld, 20 are provided for fixedly and conductively securing an outer end portion of the f irst electrical lead wire to the core wire end portion .
Because of the unique conf iguration of the groove means, the bent first electrical lead wire received therei~ forms a 25 resiliently deflectable interconnection between the spot weld and the resistor body. Accordingly, late~al vibrational forces created .
' .", . ': `
` ~ 2~785~1 ;
in the core ~ire (arising, for example, during shipping and handling of the vessel within which the anode assembly is ,L~.Led) are not rigidly resisted by the first electrical lead wire. Instead, the bent first electrical lead wire is causea to laterally flex within the groove means in response to lateral vibrational 1 ~Vl t of the core wire end portion, thereby protecting the lead wire/core wire spot weld against fatigue stress breakage .
Means are also provided for fixedly and conductiv~ly securing an outer end portion of the second electrical lead wire to the metal cap member. In a preferred form thereof, these means include an exterior side surface groove formed on the insulating sleeve and receiving the second resistor electrical lead member, and a spot weld securing an outer end portion of the second lead member to an open end portion of the cap member.
BRIE F DES~:K~ OF ~IE DRAWINGS
FIG. 1 is a schematic partial cross-sectional view through a representative metal water heater tank having operatively installed on a top end thereof a resistored sacrificial anode assembly embodying princlples of the present invention;
FIG. 2 is an enlarged scale partial cross-sectional view through the anode assembly taken along line 2-2 of FIG. 1;
FIG. 3 is a cross-sectional view through the anode assembly taken along line 3-3 of FIG. 2; and FIG. 4 is a perspective view of an internal plastic insulating sleeve portion of the anode assembly.
, ;' ' -~i 2~78~
I~TATT T~n DE SCRIPTION
Ref erring to FIGS . 1-4, the present invention provides a specially designed resi6tored sacrificial anode assenbly 10 which is operatively installed in the top end wall 12a of a representative metal water heater storage tank 12, extends into the water-filled interior of the tank, and operates to cathodically inhibit corrosion of the tank. As cross-sectionally i~lustrated ln FIG. 2, the anode assembly 10 includes a cylindrically shaped sacrificial anode member 14 having a main body portion 16, a reduced diameter neck portion 18 having an annular F-ytc.rn~l side surface indentation 20 formed therein, and an annu~ar ledge 22 formed at the ~uncture of the main body and neck portions 16,18.
Axially extending centrally through the anode member 14 is a metal core wire or rod 24 having an upper end portion 24a extending upwardly beyond the upper end of the neck portion 18.
The anode member neck portion 18 is coaxially pressed into the open lower end 26 of a cylindrical, molded plastic insulating sleeve 28 having a closed top end 30 through which a central circular hole 32 is formed. When the anode neck 18 is pressed into sleeve 28, the wire end portion 24a is received in the hole 32.
Sleeve 28, in turn, is pressed into a hollow cylindrical metal cap mem~er 36 having an enlarged diameter head portion 38, and a hollow externally threaded body portion 40 threaded ~nto the top tank end wall 12a as shown in FIG. 2. A lower end portion 40a of the body portion 40 is inwardly swaged against the body of the plastic sleeve 28 to captively retain the sleeve 28 within the cap " ' .
RACT~I'.RI I OF T~E INVE NTION
The present invention relates generally to anode devices used to inhibit corrosion in metal water heater tanks and other metal 5 liquid storage vessels and, in a preferred embodiment thereof, more particularly relates to a specially designed resistored anode assembly useful in this corrosion-inhibiting application.
Conventional metal water heater tanks, like other types oE
metal vessels used to store liquids, are subject to corrosion 10 durin~ use. To inhibit this corrosion, sacrificial anodes, normally constructed of magnesium, aluminum or zinc, are inserted into the tank. The sacrificial anode is slowly cu.~ during the corrosion protection process while generating an electrical current. As the anode is slowly depleted, it~: simultaneously 15 generated electrical current cathodically protects the ~ank against corrosion .
The service life of the anode tends to be inversely dependent upon the amount of electrical current it generates in cathodically protecting the tank. In many fresh water supplies, particularly 20 those having a hLgh mineral content, the current flow generated by the anode ls relatively high, resulting in a corresponding decrease in the useful life of the anode. In order to control the rate of uc,~ u.~.~Lion of a sacrificial anode, various anode ~ u~Lions ~ 2178511 have been proposed in which a resistor is inuuL~ ted in the anode, and electrically connected between the anode and its protected tank, to automatically regulate the electrlcal ourrent generated by the anode during its operation and thereby increa~;e 5 the 6ervice lif e of the anode .
While these resistored anode devices typically extended anode life, many of them also tended to be of a relativ~ely complex construction, rather difficult to assemble, and relatively expensLve to fabricate.
Many of these problems are essentially eliminated by a prior art sacrificial anode assembly that in~.L~o-~es, in a simplified manner, an ordinary barrel-type carbon resistor into the interior of the assembly. This prior art anode assembly include6 a cylindrlcal plastic insulating sleeve captively retained within the metal cap portion of the anode assembly and having a closed end with a central opening through which an end portion of the metal anode body core rod extends. A diametrically extending groove, which intersects the central sleeve opening~ is formed in the closed sleeve end.
The cylindrical resistor body is disposed in a radial portion of the sleeve end groove, with one of the resis~or end leads being radially extended over the anode rod end and soldered thereto. The other resistor end lead passes through an axially extending exterior side surface groove in the insulating sleeve and is soldered at its outer end to an external metal cap portion of the anode assembly.
- ~ 2~
Although this method of operatively positioning a resistor in a sacrif icial anode assembly provides a worthwhile reduction in assembly time and cost, and provides the desired regulation of anode current generation, it has been found that it can create a problem relating to the tjL~u~:LuLal integrity of the completed anode assembly. Specifically, it has been found that in certain shipping orientations of the tank in which the anode assembly L8 installed, harmonic vibrations may be created within the central anode core rod which are transmitted to the solder ~oint connectillg a resistor end lead to the rod. These vibrations can fatigue and break the rod/lead solder ~oint, thereby rendering the anode assembly inoperative . .
From the foregoing it can be seen that it would be desirable to provide a sacrificial anode assembly, of the type having an insuiating sleeve-installed resistor as generally described above, which substantially eliminates this vibration-caused solder ~oint breakage problem. It is accordingly an ob~ect of the present invention to provide such a sacrificial anode assembly.
SUM~ARY OF THE lrlV~nlll In carrying out principles of the present invention, in accordance with a preferred ~ L thereof, a specially designed resistored sacrificial anode assembly is provided for use in a metal liquid storage to inhibit vessel corrosion The anode assembly may be secured to the vessel, to extend into its liquid filled interior, and ~ ncll~A~ an elongated metal anode member having a core wire extending longitl~in~l~y . .
` ~ 21~85~1 therethrough and pro~ecting outwardly through an end thereof. An insulating sleeve mem~er, preferably formed from a molded plastic material, receives and is captively retained on this anode member end and has an ond wall portlon with a central opening therein that 5 receives an end portion of the core wire. A hollcw metal cap member received and is captively retained on the insulatLng sleeve member .
An electrical resistor is ~ po~d within the cap member and has a cylindrical body portion with first and Gecond ends. First 10 and second electrical lead wires respectively extend outwardly from the first and second resistor body ends.
Exterior surface groove means are formed in the end wall portion of the insulating sleeve member and receive the resistor body in a manner positioning its length perpendicular to the 15 longftudinal axis of the insulating sleeve. These groove means have a curved portion through which the first electrical lead wire extends to the core wire end portion, the groove means being configured to permit lateral ~. t of the first electrical lead wire therein. Means, representatively in the form of a spot weld, 20 are provided for fixedly and conductively securing an outer end portion of the f irst electrical lead wire to the core wire end portion .
Because of the unique conf iguration of the groove means, the bent first electrical lead wire received therei~ forms a 25 resiliently deflectable interconnection between the spot weld and the resistor body. Accordingly, late~al vibrational forces created .
' .", . ': `
` ~ 2~785~1 ;
in the core ~ire (arising, for example, during shipping and handling of the vessel within which the anode assembly is ,L~.Led) are not rigidly resisted by the first electrical lead wire. Instead, the bent first electrical lead wire is causea to laterally flex within the groove means in response to lateral vibrational 1 ~Vl t of the core wire end portion, thereby protecting the lead wire/core wire spot weld against fatigue stress breakage .
Means are also provided for fixedly and conductiv~ly securing an outer end portion of the second electrical lead wire to the metal cap member. In a preferred form thereof, these means include an exterior side surface groove formed on the insulating sleeve and receiving the second resistor electrical lead member, and a spot weld securing an outer end portion of the second lead member to an open end portion of the cap member.
BRIE F DES~:K~ OF ~IE DRAWINGS
FIG. 1 is a schematic partial cross-sectional view through a representative metal water heater tank having operatively installed on a top end thereof a resistored sacrificial anode assembly embodying princlples of the present invention;
FIG. 2 is an enlarged scale partial cross-sectional view through the anode assembly taken along line 2-2 of FIG. 1;
FIG. 3 is a cross-sectional view through the anode assembly taken along line 3-3 of FIG. 2; and FIG. 4 is a perspective view of an internal plastic insulating sleeve portion of the anode assembly.
, ;' ' -~i 2~78~
I~TATT T~n DE SCRIPTION
Ref erring to FIGS . 1-4, the present invention provides a specially designed resi6tored sacrificial anode assenbly 10 which is operatively installed in the top end wall 12a of a representative metal water heater storage tank 12, extends into the water-filled interior of the tank, and operates to cathodically inhibit corrosion of the tank. As cross-sectionally i~lustrated ln FIG. 2, the anode assembly 10 includes a cylindrically shaped sacrificial anode member 14 having a main body portion 16, a reduced diameter neck portion 18 having an annular F-ytc.rn~l side surface indentation 20 formed therein, and an annu~ar ledge 22 formed at the ~uncture of the main body and neck portions 16,18.
Axially extending centrally through the anode member 14 is a metal core wire or rod 24 having an upper end portion 24a extending upwardly beyond the upper end of the neck portion 18.
The anode member neck portion 18 is coaxially pressed into the open lower end 26 of a cylindrical, molded plastic insulating sleeve 28 having a closed top end 30 through which a central circular hole 32 is formed. When the anode neck 18 is pressed into sleeve 28, the wire end portion 24a is received in the hole 32.
Sleeve 28, in turn, is pressed into a hollow cylindrical metal cap mem~er 36 having an enlarged diameter head portion 38, and a hollow externally threaded body portion 40 threaded ~nto the top tank end wall 12a as shown in FIG. 2. A lower end portion 40a of the body portion 40 is inwardly swaged against the body of the plastic sleeve 28 to captively retain the sleeve 28 within the cap " ' .
- 2~7~51 1 I
member body 40. This swaging also forces an annular portion 34 of the sleeve 28 lnto the annular groove 20.
To control and maintain the protective anode current at a suitable level, the anode assembly 10 is provided wiLth a barrel-shaped resi6tor 42 (see FIGS. 3 and 4) having metal lead wires 44 and 46 extending outwardly from its opposite ends. To support the re~iistor 42 on the top end of the sleeve 28, a specially configured exterior surface groove 48 is formed in the sleeve. As best illustrated in FIGS. 3 and 4, the groove 48 has a portion 48a extending diametrically across the closed top sleeve end 30 from opposite sides of the circular sleeve opening 32: a portion 48b extending generally chordwise across the sleeve end 30 and having a Lr Illt~V~L~ely enlarged portion 48c; a curved portion 48d joining ad~acent left ends of portions 48a and 48b: and a portion 48e extending axially along the external side surface of the sleeve 28 from the right end of the groove portion 48b.
Accordingly, the exterior groove 48 sequentially extends upwardly along the body of the sleeve, across the top end of the sleeve in a chordwise direction, bends around at groove portion 48d, and then extends diametrically across the top sleeve end opening 32. The chordwise groove portion 48c is representatively illustrated as being parallel to the diametrically extending groove portion 48a. However, groove portion 48c could be oriented at an angle to groove portion 48a if desired.
zs The groove portions 44a-44c on the top end of tihe sleeve 28 are vertically deeper than the resistor 42 (see FIG. 2), all of the . .
2 1 7 8 ~ 1 l ' `
groove portions 44a-44e are laterally wider than the resistor leads 44 and 46, and the horizontal width and length of the laterally enlarged groove portion 48c are sized to permit the resistor 42 to be snap-fitted into the groove portion 48c to inhibit movement of the resistor relative to the groove portion 48c. Alternatively, the groove portion 48c could be configured to permit at least limited l v~ L of the resistor within the groove portion 48c.
Prior to the insertion of the sleeve 28 within the body portion 40 of the cap member 36, the resistor 42 is snap-fitted into the laterally enlarged groove portion 48c: the resistor lead 44 i8 extended along the groove portions 48b,48d and 48a and spot welded to the core wire portion 24a as at 50 ~ see FIG. 3 ); and the resistor lead wire 46 is extended downwardly through the vertical groove portion 48e. After the anode member-supported sleeve 28 is operatively inserted into the body of the cap member 36, the outer end of the lead 46 is spot welded, as at 52 (6ee FIG. 2), to the lower end of thc cap member body portion 40. ~he completed anode assembly lO is then ready to be threaded into the tank wall 12a as illustrated in FIG. 2.
In prior art anode insulating sleeves similar to sleeve 28, the resistor is fixedly held in a diametrically extending groove formed in the closed sleeve end. Using this conventional resistor support configuration, the upper end of the anode care wire, and thus the core wire/lead wire spot weld, is longit~ in~l~y aligned with the cylindrical resistor body fixedly held on the closed sleeve end. Accordingly, lateral vibrational movements of the core 217~5~1 f wire are axially resisted by the resistor lead wire welded thereto which, with respect to such lateral vibrational movements of the core wire, forms an essentially rigid connection between the spot weld and the f acing end of the resistor body . This essentially 5 rigid connection between the spot weld and the facing resistor body end can fatigue and break the spot weld, the lead wire, or the resistor body, thereby undesirably breaking the electrical current path between the anode core wire and the metal anode cap.
In sharp contra6t, due to the unique conf iguration of the top 10 sleeve end portion of the groove 48 in the present invention, rigid vibrational forces transmitted to the spot weld 50 (seQ FIG. 30) from the core wire (arising, for example, when the tank 12 is shipped in a horizontal orientation) are substantially eliminated.
This desirable result i5 achieved via the lateral shifting of the 15 resistor 42 out of axial alignment with the groove portion 48a, and the generally ~-shaped configuration of the connected groove portions 48a,48b,48d.
Specifically, it can be seen in FIGS. 3 and 4 that the spot weld 50 is resiliently connected to the left end of the resistor 42 20 by the generally U-shaped lead wire 44 received in the connected groove portions 48a,48b,48d. A vibrational shift of the spot weld 50 to the left as viewed in FIG. 3 is not met with a rigid lead wire resistance. Instead, such leftward vibrational shift of the spot weld 50 simply causes the bent portion of the lead wire 44 to 25 resiliently flex, and shift leftwardly within its groove portion 48d, without exerting an appreciable axial force on the resistor .
2~7~511 42. In a similar manner, a vibrational shift of the spot weld 50 to the right is not met with a rigid lead wire resistance.
Instead, such rightward vibrational shift of the spot weld 50 simply causes the bent portion of the lead wire 44 to resiliently 5 flex, and shift rightwardly within its groove portion 48d, without exerting an appreciable axial force on the resistor 42.
This resilient lead wire interconnection between the spot weld 50 and the resistor 42 thus advantageously functions to protect the weld against vibrational fatigue breakage. ~he top sleeve end 10 groove modification embodied in the present invention may be easily and ;n~ r~n~;vely inco~ ed into the anode assembly 10 to appreciably increase both its durability and reliability.
The foregoing detailed description is to be clearly u~ld~l~,Lood as being given by way of illustration and example only, the ~pirit 15 and scope of the present invention being limited solely by the appended claims.
.
member body 40. This swaging also forces an annular portion 34 of the sleeve 28 lnto the annular groove 20.
To control and maintain the protective anode current at a suitable level, the anode assembly 10 is provided wiLth a barrel-shaped resi6tor 42 (see FIGS. 3 and 4) having metal lead wires 44 and 46 extending outwardly from its opposite ends. To support the re~iistor 42 on the top end of the sleeve 28, a specially configured exterior surface groove 48 is formed in the sleeve. As best illustrated in FIGS. 3 and 4, the groove 48 has a portion 48a extending diametrically across the closed top sleeve end 30 from opposite sides of the circular sleeve opening 32: a portion 48b extending generally chordwise across the sleeve end 30 and having a Lr Illt~V~L~ely enlarged portion 48c; a curved portion 48d joining ad~acent left ends of portions 48a and 48b: and a portion 48e extending axially along the external side surface of the sleeve 28 from the right end of the groove portion 48b.
Accordingly, the exterior groove 48 sequentially extends upwardly along the body of the sleeve, across the top end of the sleeve in a chordwise direction, bends around at groove portion 48d, and then extends diametrically across the top sleeve end opening 32. The chordwise groove portion 48c is representatively illustrated as being parallel to the diametrically extending groove portion 48a. However, groove portion 48c could be oriented at an angle to groove portion 48a if desired.
zs The groove portions 44a-44c on the top end of tihe sleeve 28 are vertically deeper than the resistor 42 (see FIG. 2), all of the . .
2 1 7 8 ~ 1 l ' `
groove portions 44a-44e are laterally wider than the resistor leads 44 and 46, and the horizontal width and length of the laterally enlarged groove portion 48c are sized to permit the resistor 42 to be snap-fitted into the groove portion 48c to inhibit movement of the resistor relative to the groove portion 48c. Alternatively, the groove portion 48c could be configured to permit at least limited l v~ L of the resistor within the groove portion 48c.
Prior to the insertion of the sleeve 28 within the body portion 40 of the cap member 36, the resistor 42 is snap-fitted into the laterally enlarged groove portion 48c: the resistor lead 44 i8 extended along the groove portions 48b,48d and 48a and spot welded to the core wire portion 24a as at 50 ~ see FIG. 3 ); and the resistor lead wire 46 is extended downwardly through the vertical groove portion 48e. After the anode member-supported sleeve 28 is operatively inserted into the body of the cap member 36, the outer end of the lead 46 is spot welded, as at 52 (6ee FIG. 2), to the lower end of thc cap member body portion 40. ~he completed anode assembly lO is then ready to be threaded into the tank wall 12a as illustrated in FIG. 2.
In prior art anode insulating sleeves similar to sleeve 28, the resistor is fixedly held in a diametrically extending groove formed in the closed sleeve end. Using this conventional resistor support configuration, the upper end of the anode care wire, and thus the core wire/lead wire spot weld, is longit~ in~l~y aligned with the cylindrical resistor body fixedly held on the closed sleeve end. Accordingly, lateral vibrational movements of the core 217~5~1 f wire are axially resisted by the resistor lead wire welded thereto which, with respect to such lateral vibrational movements of the core wire, forms an essentially rigid connection between the spot weld and the f acing end of the resistor body . This essentially 5 rigid connection between the spot weld and the facing resistor body end can fatigue and break the spot weld, the lead wire, or the resistor body, thereby undesirably breaking the electrical current path between the anode core wire and the metal anode cap.
In sharp contra6t, due to the unique conf iguration of the top 10 sleeve end portion of the groove 48 in the present invention, rigid vibrational forces transmitted to the spot weld 50 (seQ FIG. 30) from the core wire (arising, for example, when the tank 12 is shipped in a horizontal orientation) are substantially eliminated.
This desirable result i5 achieved via the lateral shifting of the 15 resistor 42 out of axial alignment with the groove portion 48a, and the generally ~-shaped configuration of the connected groove portions 48a,48b,48d.
Specifically, it can be seen in FIGS. 3 and 4 that the spot weld 50 is resiliently connected to the left end of the resistor 42 20 by the generally U-shaped lead wire 44 received in the connected groove portions 48a,48b,48d. A vibrational shift of the spot weld 50 to the left as viewed in FIG. 3 is not met with a rigid lead wire resistance. Instead, such leftward vibrational shift of the spot weld 50 simply causes the bent portion of the lead wire 44 to 25 resiliently flex, and shift leftwardly within its groove portion 48d, without exerting an appreciable axial force on the resistor .
2~7~511 42. In a similar manner, a vibrational shift of the spot weld 50 to the right is not met with a rigid lead wire resistance.
Instead, such rightward vibrational shift of the spot weld 50 simply causes the bent portion of the lead wire 44 to resiliently 5 flex, and shift rightwardly within its groove portion 48d, without exerting an appreciable axial force on the resistor 42.
This resilient lead wire interconnection between the spot weld 50 and the resistor 42 thus advantageously functions to protect the weld against vibrational fatigue breakage. ~he top sleeve end 10 groove modification embodied in the present invention may be easily and ;n~ r~n~;vely inco~ ed into the anode assembly 10 to appreciably increase both its durability and reliability.
The foregoing detailed description is to be clearly u~ld~l~,Lood as being given by way of illustration and example only, the ~pirit 15 and scope of the present invention being limited solely by the appended claims.
.
Claims (5)
1. A water heater comprising:
a metal tank adapted to hold a quantity of water to be heated, and a sacrificial anode assembly supported on said metal tank, said sacrificial anode assembly including:
an elongated metal anode member extending into the interior of said metal tank, said anode member having a core wire extending axially therethrough and projecting outwardly through an end of said anode member, an insulating sleeve member receiving and being captively retained on said end of said anode member, said insulating sleeve member having:
an end wall portion with a central opening that receives an end portion of said core wire, a first exterior surface groove formed in said end wall portion and having a first generally straight section extending into said central opening and having an end spaced apart form therefrom, a second generally straight section offset from said first section and having an end spaced apart from said central opening, and a curved third section joining said ends of said first and second sections, and a second exterior surface groove formed in and extending generally axially along a side wall portion of said insulating sleeve member, said second exterior surface groove defining a continuation of said second section of said first exterior surface groove;
a hollow metal cap member receiving and captively retained on said insulating sleeve member, said cap member being secured to said metal tank; and an electrical resistor having:
cylindrical body portion received in said second section of said first exterior surface groove in a spaced apart relationship with said end thereof, a first electrical lead wire extending from one end of said resistor body portion sequentially through a portion of said second groove section, said curved third groove section, said first groove section, and across said central opening, said first electrical lead wire having an outer end portion fixedly and conductively secured to said end portion of said core wire, and a second electrical lead wire extending from the opposite end of said resistor body portion and through said second exterior surface groove, said second electrical lead wire having an outer end fixedly and conductively secured to said metal cap member.
a metal tank adapted to hold a quantity of water to be heated, and a sacrificial anode assembly supported on said metal tank, said sacrificial anode assembly including:
an elongated metal anode member extending into the interior of said metal tank, said anode member having a core wire extending axially therethrough and projecting outwardly through an end of said anode member, an insulating sleeve member receiving and being captively retained on said end of said anode member, said insulating sleeve member having:
an end wall portion with a central opening that receives an end portion of said core wire, a first exterior surface groove formed in said end wall portion and having a first generally straight section extending into said central opening and having an end spaced apart form therefrom, a second generally straight section offset from said first section and having an end spaced apart from said central opening, and a curved third section joining said ends of said first and second sections, and a second exterior surface groove formed in and extending generally axially along a side wall portion of said insulating sleeve member, said second exterior surface groove defining a continuation of said second section of said first exterior surface groove;
a hollow metal cap member receiving and captively retained on said insulating sleeve member, said cap member being secured to said metal tank; and an electrical resistor having:
cylindrical body portion received in said second section of said first exterior surface groove in a spaced apart relationship with said end thereof, a first electrical lead wire extending from one end of said resistor body portion sequentially through a portion of said second groove section, said curved third groove section, said first groove section, and across said central opening, said first electrical lead wire having an outer end portion fixedly and conductively secured to said end portion of said core wire, and a second electrical lead wire extending from the opposite end of said resistor body portion and through said second exterior surface groove, said second electrical lead wire having an outer end fixedly and conductively secured to said metal cap member.
2. The water heater of Claim 1 wherein:
said first groove section has a laterally enlarged portion that receives said resistor body portion and is configured to essentially prevent movement thereof relative to said insulating sleeve member.
said first groove section has a laterally enlarged portion that receives said resistor body portion and is configured to essentially prevent movement thereof relative to said insulating sleeve member.
3. The water heater of Claim 1 wherein:
said outer end portion of said first lead wire is spot welded to said end portion of said core wire.
said outer end portion of said first lead wire is spot welded to said end portion of said core wire.
4. The water heater of Claim 1 wherein:
said insulating sleeve member has a generally cylindrical configuration, said first groove section extends generally diametrically across said end wall portion of said insulating sleeve member, and said second groove section extends generally chordwise across said end wall portion of said insulating sleeve member.
said insulating sleeve member has a generally cylindrical configuration, said first groove section extends generally diametrically across said end wall portion of said insulating sleeve member, and said second groove section extends generally chordwise across said end wall portion of said insulating sleeve member.
5. The water heater of Claim 1 wherein:
said insulating sleeve member is molded from a plastic material.
said insulating sleeve member is molded from a plastic material.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US08/004,724 US5256267A (en) | 1993-01-14 | 1993-01-14 | Resistored sacrificial anode assembly for metal tank |
US08/004,724 | 1993-01-14 | ||
CA002111268A CA2111268C (en) | 1993-01-14 | 1993-12-13 | Resistored sacrificial anode assembly for metal tank |
Publications (2)
Publication Number | Publication Date |
---|---|
CA2178511A1 CA2178511A1 (en) | 1994-07-15 |
CA2178511C true CA2178511C (en) | 2000-07-18 |
Family
ID=25676846
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CA002178511A Expired - Fee Related CA2178511C (en) | 1993-01-14 | 1993-12-13 | Resistored sacrificial anode assembly for metal tank |
Country Status (1)
Country | Link |
---|---|
CA (1) | CA2178511C (en) |
-
1993
- 1993-12-13 CA CA002178511A patent/CA2178511C/en not_active Expired - Fee Related
Also Published As
Publication number | Publication date |
---|---|
CA2178511A1 (en) | 1994-07-15 |
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Date | Code | Title | Description |
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EEER | Examination request | ||
MKLA | Lapsed |
Effective date: 20131213 |