US1599161A - Core for induction furnaces - Google Patents

Core for induction furnaces Download PDF

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Publication number
US1599161A
US1599161A US412550A US41255020A US1599161A US 1599161 A US1599161 A US 1599161A US 412550 A US412550 A US 412550A US 41255020 A US41255020 A US 41255020A US 1599161 A US1599161 A US 1599161A
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Prior art keywords
core
jacket
channel
furnace
rod
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Expired - Lifetime
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US412550A
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Jr Charles A Brayton
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INDUCTION FURNACE Co
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INDUCTION FURNACE Co
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Priority to US412550A priority Critical patent/US1599161A/en
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B6/00Heating by electric, magnetic or electromagnetic fields
    • H05B6/02Induction heating
    • H05B6/16Furnaces having endless cores
    • H05B6/20Furnaces having endless cores having melting channel only

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  • This invention relates to the forming of the channels in the construction of electric induction furnaces.
  • the purpose of my invention is to roduce a fusible core that can be suspende within molds, such as are utilized in the construction of induction furnaces of the closed channel type, such as I have shown in my application of September 24, 1920, Serial No. 412,551.
  • Another purpose is to provide a fusible core which can be utilized in starting a furnace of the aforesaid type that will avoid irregular resistances upon the starting of the furnace.
  • a further purpose is to provide a temporary metallic secondar that may be used to start the furnace wit out first charging the same with molten metal.
  • FIGs. 1 and 2 are cross sectional views 0% channel wall molds showing the relative position of the cores to the molds;"Fig. 3 is a transverse section of a mold and core taken at the line 11 of Fig. 1; Figs. 4 and 5 are enlarged views of the terminals of the core.
  • Fig. 1 which represents an embodiment of my invention as used in forming channels of a U-shape
  • 6 represents a cross section of the primary
  • 7 represents the base or supporting plate of t e bath basin, the contour of which is shown in dotted lines 8.
  • the channel-wall mold 9 is formed of expanded or other. suitable metal which may be easily bent to the desired shape.
  • FIG. 2 a representation of the adap ta bility of the invention in, molding a modified V-shaped channel is shown.
  • the core is of sufficient length to permit the terminals to project into the bath and may be constructed of a relatively thin circular bent tubular jacket-13, Fi 3, a solid round core rodl i threaded at t e ends and a removable spacing bar 15. .
  • a tie bar 12 may connect the terminals of the core as shown at 16, Figs. 4 and 5.
  • the mold 9 is formed to the desired shape with the core unit on the inside of the same after which the ends of the mold are inserted in the openings of the basin supporting plate 7 and bent outwardly to form a seat as shown at 10, Figs. 1 and 2, and the refractory material molded about the core in the manner I have set forth Serial No. 412,551 filed September 24, 1920.
  • the core jacket 13 which I prefer to make from a thin tube is held in definite relation to the core rod 14 by wedging bar 15, which exerts a binding force between the rod and acket and positions the latter with relation to the core rod so that a longitudinal space 20 may be provided within the jacket after the bar 15 has been withdrawn.
  • the core is held in coaxial position with relation to the mold by suitable means and the plastic refractory material is then dropped into the mold and tamped to a uniform consistency about the core.
  • the bath basin is then' formed of the same material with the terminals of the core protruding into the bath basin.
  • the lining During the time the lining is passing through the drying and setting period it gradually shrinks away from the core jacket and upon the completion of this action there is a small space between the core jacket and the refractor material.
  • the bars 15 are withdrawn a ter this period and the furnace may be started-by charging the'basin with mo ten metal or with scrap chips heaped about the tie bar, which 'ma act as a conductor between the termina s of the core.
  • the core rod expands longitudinally and diametriin my application lows :-The elongation of that part of the core designated at 22 causes the core rod 14 to shift outwardly from the primary 6 into the hollow space 20 of the core jacket 13, with a corresponding shifting action taking place between the tie bar 12 and the terminals 16. As the longitudinal expansion greatly exceeds the diametrical expansion, the'center of the rod is shifted towards the space 20 and away from the inside wall of the .core jacket 13.
  • the tie bar is maintained in conductive contact with the core, and thereafter until the core is heated to the fusing-point and becomes absorbed by the furnace charge.
  • an expanding channel core wherein an unfilled space is provided longitudinally of the channel centre, whereby part of, said space ma be occupied upon a subsequent shifting 0 the core members.
  • I r y 2.
  • means for I coring a closed channel said means comprising a relatively thin coring jacket bent to form a channel communication at the ends thereof with the interior of the fur nace, and an electrically conducting core rod within the jacket and having the longitudinal axis thereof substantially parallel to that of the jacket, the surface on the outer portion of the bend being separated from the adjacent walls of the jacket, whereby when the rodis subsequently heated, the said surface of the rod will approach, without forcing against such adjacent walls of the jacket.
  • an expanding core forforniing a closed channel wherein an unfilled space and an electrically conducting means is provided, whereby the subsequent cross-sectional increase of said conducting means may occupy part of said space.
  • An expandi core for formingtne channels of an in uction furnace comprising a relatively thincoring jacket, the expanding pressure of which will not be materially greater than the subsequent hydrostatic pressure exerted by the bath upon the channel walls and an electrically conducting member the major portion of the exterior surfaces of which are in spaced relation to said jacket, said members having terminal connecting means constituting the secondary of the furnace.
  • an expanding and electrically conducting channel core wherein the-expansion of one member of the core displaces the longitudinal axis thereof toward the centre of the cored area, and the expansion of another member of the core is in a circumferential direction about the centre of the cored area.
  • a tubular channel communicating at its ends with the interior of the furnace, an expanding core member a portion of which is eccentric to the channel and enclosed thereby, whereby when heated the longitudinal expansion of the core member displaces the axis of said corl'e member toward the center of the channe r '7.
  • means for coring a closed-channel said means comprising a relatively thin coring jacket and .an electrically conducting core rod therefor, substantially smaller in diameter than the inside of the jacket.
  • means for coring a closed channel including a coring jacket, an electrically conducting core rod within said jacket and having surfaces materialy spaced from the jacket wall and a connection across the terminals of the core rod whereby the core may become the closed secondary of the furnace.
  • a wall portion having a tubular channel communicating at the ends thereof with the interior of the furnace, an expanding core located within such channel and a removable core member for maintaining the expandin core in definite relation to the channel whi e the channel is being formed, means whereby said relation is temporarily maintained when such removable core member is withdrawn, said relation admitting subse uent shifting of the core, when expanded b eat, in a direction awayfrom the channe wall.
  • An expanding core for forming the channels of an induction furnace comprising. a relatively thin metal coring jacket, the
  • a channel core a relatively thin coring jacket, an electrically conducting core rod within the jacket, a spacing bar maintaining a given surface of said core rod in spaced relation to said jacket and short circuiting means for connecting the terminals of said core rod.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Furnace Details (AREA)

Description

Sept. 7 1926 1 1,599,161
c. A. BRAYTON, JR
CORE FOR INDUCTION FURNACES Filed Sept. 24, 1920 ATTORNEYS Patented Sept. 7, 1926.
UNITED STATES 1,599,161 PATENT OFFICE.
CHARLES A. BRAYTON, JR., OF CLEVELAND, OHIO, ASSIGNOR TO THE INDUCTION FUR- NACE COMPANY, OF CLEVELAND, OHIO, A CORPORATION OF OHIO.
CORE FOR INDUCTION FURNACES.
' Application filed September 24, 1920, Serial No. 412,550.
This invention relates to the forming of the channels in the construction of electric induction furnaces.
The purpose of my invention is to roduce a fusible core that can be suspende within molds, such as are utilized in the construction of induction furnaces of the closed channel type, such as I have shown in my application of September 24, 1920, Serial No. 412,551.
Another purpose is to provide a fusible core which can be utilized in starting a furnace of the aforesaid type that will avoid irregular resistances upon the starting of the furnace.
A furtherpurposeis to prevent the occurrence of cracks along the inside of the channel wall heretofore caused by solid fusible cores expanding laterally against the refractory material and cracking the same.
A further purpose is to provide a temporary metallic secondar that may be used to start the furnace wit out first charging the same with molten metal.
Additional purposes will be evident in the specification and claims.
An embodiment of my invention is set forth in the drawings and is hereinafter more fully described in reference to the sameand the essential features of the invention are set out in the claims. i
In the drawin s Figs. 1 and 2 are cross sectional views 0% channel wall molds showing the relative position of the cores to the molds;"Fig. 3 is a transverse section of a mold and core taken at the line 11 of Fig. 1; Figs. 4 and 5 are enlarged views of the terminals of the core.
Referring to the parts designated by numerals, in Fig. 1 which represents an embodiment of my invention as used in forming channels of a U-shape, 6 represents a cross section of the primary, while 7 represents the base or supporting plate of t e bath basin, the contour of which is shown in dotted lines 8. The channel-wall mold 9 is formed of expanded or other. suitable metal which may be easily bent to the desired shape.
In Fig. 2, a representation of the adap ta bility of the invention in, molding a modified V-shaped channel is shown. I
The core is of sufficient length to permit the terminals to project into the bath and may be constructed of a relatively thin circular bent tubular jacket-13, Fi 3, a solid round core rodl i threaded at t e ends and a removable spacing bar 15. .A tie bar 12 may connect the terminals of the core as shown at 16, Figs. 4 and 5.
The mold 9 is formed to the desired shape with the core unit on the inside of the same after which the ends of the mold are inserted in the openings of the basin supporting plate 7 and bent outwardly to form a seat as shown at 10, Figs. 1 and 2, and the refractory material molded about the core in the manner I have set forth Serial No. 412,551 filed September 24, 1920. The core jacket 13 which I prefer to make from a thin tube is held in definite relation to the core rod 14 by wedging bar 15, which exerts a binding force between the rod and acket and positions the latter with relation to the core rod so that a longitudinal space 20 may be provided within the jacket after the bar 15 has been withdrawn.
The threaded terminals of the core rod pass thru elongated openings 17 of the tie bar 12 and the .bar is secured to the rod by nuts 21, that clamp the bar on the washers 23, which rest on the ends of the core jacket as shown in Fig. 4, with just suflicient pressure to insure good conduction but to also permit an expanding movement of the rod. v
The core is held in coaxial position with relation to the mold by suitable means and the plastic refractory material is then dropped into the mold and tamped to a uniform consistency about the core. The bath basin is then' formed of the same material with the terminals of the core protruding into the bath basin.
During the time the lining is passing through the drying and setting period it gradually shrinks away from the core jacket and upon the completion of this action there is a small space between the core jacket and the refractor material. The bars 15 are withdrawn a ter this period and the furnace may be started-by charging the'basin with mo ten metal or with scrap chips heaped about the tie bar, which 'ma act as a conductor between the termina s of the core.
As the resistance caused by the current induced in the same heats the core, the core rod expands longitudinally and diametriin my application lows :-The elongation of that part of the core designated at 22 causes the core rod 14 to shift outwardly from the primary 6 into the hollow space 20 of the core jacket 13, with a corresponding shifting action taking place between the tie bar 12 and the terminals 16. As the longitudinal expansion greatly exceeds the diametrical expansion, the'center of the rod is shifted towards the space 20 and away from the inside wall of the .core jacket 13. After the core jacket expands in the same manner, until the void caused by the drying of the lining is filled, it is then opposed by the refracto lining, and a subsequent contraction or adding takes place in the walls of the jacket due to the expandin movement of the jacket being restricted. he pressure on the refractory material caused by this diversion in the direction of the expansion of the jacket, how
ever, is greatly reduced by making the same of relatively thin metal.
During the period the expanding movements of the jacket and core rod are taking place the tie bar is maintained in conductive contact with the core, and thereafter until the core is heated to the fusing-point and becomes absorbed by the furnace charge.
It is readily seen that in my invention I have provided an inexpensive means for properly molding the closed channels of an induction furnace that requires no extra labor in removing the core at the time the furnace is ready for operation and that a core such as I have herein set forth will ex-' pand without cracking the channel lining and that it will present and maintain a closed secondary without arcing or breaking the current path. Furthermore, a chan-' nel of uniform cross-section is assured by the use of such a core.
Having thus described my --invention, I claim:
1. In an induction furnace, an expanding channel core wherein an unfilled space is provided longitudinally of the channel centre, whereby part of, said space ma be occupied upon a subsequent shifting 0 the core members. I r y 2. In an induction furnace, means for I coring a closed channel, said means comprising a relatively thin coring jacket bent to form a channel communication at the ends thereof with the interior of the fur nace, and an electrically conducting core rod within the jacket and having the longitudinal axis thereof substantially parallel to that of the jacket, the surface on the outer portion of the bend being separated from the adjacent walls of the jacket, whereby when the rodis subsequently heated, the said surface of the rod will approach, without forcing against such adjacent walls of the jacket.
3. In an induction furnace, an expanding core forforniing a closed channel wherein an unfilled space and an electrically conducting means is provided, whereby the subsequent cross-sectional increase of said conducting means may occupy part of said space.
4. An expandi core for formingtne channels of an in uction furnace, comprising a relatively thincoring jacket, the expanding pressure of which will not be materially greater than the subsequent hydrostatic pressure exerted by the bath upon the channel walls and an electrically conducting member the major portion of the exterior surfaces of which are in spaced relation to said jacket, said members having terminal connecting means constituting the secondary of the furnace.
5. In an induction furnace, an expanding and electrically conducting channel core .wherein the-expansion of one member of the core displaces the longitudinal axis thereof toward the centre of the cored area, and the expansion of another member of the core is in a circumferential direction about the centre of the cored area.
6. In an induction furnace, a tubular channel communicating at its ends with the interior of the furnace, an expanding core member a portion of which is eccentric to the channel and enclosed thereby, whereby when heated the longitudinal expansion of the core member displaces the axis of said corl'e member toward the center of the channe r '7. In an induction furnace, means for coring a closed-channel, said means comprising a relatively thin coring jacket and .an electrically conducting core rod therefor, substantially smaller in diameter than the inside of the jacket. 8. In an induction furnace, means for coring a closed channel including a coring jacket, an electrically conducting core rod within said jacket and having surfaces materialy spaced from the jacket wall and a connection across the terminals of the core rod whereby the core may become the closed secondary of the furnace.-
9. Inan induction furnace, a wall portion having a tubular channel communicating at the ends thereof with the interior of the furnace, an expanding core located within such channel and a removable core member for maintaining the expandin core in definite relation to the channel whi e the channel is being formed, means whereby said relation is temporarily maintained when such removable core member is withdrawn, said relation admitting subse uent shifting of the core, when expanded b eat, in a direction awayfrom the channe wall.
10. An expanding core for forming the channels of an induction furnace, comprising. a relatively thin metal coring jacket, the
expanding pressure of which will not be materially greater than the subsequent hydrostatic pressure exerted by the bath upon the channel walls, a removable spacing bar and an electrically conducting member with terminal connecting means constituting the secondary of the furnace.
11. In a channel core, a relatively thin coring jacket, an electrically conducting core rod within the jacket, a spacing bar maintaining a given surface of said core rod in spaced relation to said jacket and short circuiting means for connecting the terminals of said core rod.
12. In a fusible core, a relatively thin 15 metallic jacket, a core rod therefor, a spacing element for maintaining the jacket and rod in relative position, and an adjustable connecting bar whereby the terminals of said core rod may be conductively connected. 2 In testimony whereof, I hereunto afiix my signature.
CHARLES A. BRAYTON, JR.
US412550A 1920-09-24 1920-09-24 Core for induction furnaces Expired - Lifetime US1599161A (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2427817A (en) * 1945-05-24 1947-09-23 Tama Manuel Submerged resistor electric induction furnace
US2538979A (en) * 1941-08-19 1951-01-23 Applic Electro Thermiques Soc Induction furnace
US6153130A (en) * 1998-04-23 2000-11-28 Gradmatic Equipment Inc. Method of installing a form in a foundry furnace

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2538979A (en) * 1941-08-19 1951-01-23 Applic Electro Thermiques Soc Induction furnace
US2427817A (en) * 1945-05-24 1947-09-23 Tama Manuel Submerged resistor electric induction furnace
US6153130A (en) * 1998-04-23 2000-11-28 Gradmatic Equipment Inc. Method of installing a form in a foundry furnace

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