US2800555A - Low amperage circuit interrupter - Google Patents

Low amperage circuit interrupter Download PDF

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Publication number
US2800555A
US2800555A US450760A US45076054A US2800555A US 2800555 A US2800555 A US 2800555A US 450760 A US450760 A US 450760A US 45076054 A US45076054 A US 45076054A US 2800555 A US2800555 A US 2800555A
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bimetallic element
metallic film
metallic
insulating film
electrical insulating
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US450760A
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Edward V Sundt
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SUNDT ENGINEERING Co
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SUNDT ENGINEERING Co
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H81/00Protective switches in which contacts are normally closed but are repeatedly opened and reclosed as long as a condition causing excess current persists, e.g. for current limiting
    • H01H81/02Protective switches in which contacts are normally closed but are repeatedly opened and reclosed as long as a condition causing excess current persists, e.g. for current limiting electrothermally operated
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T29/00Metal working
    • Y10T29/49Method of mechanical manufacture
    • Y10T29/49002Electrical device making
    • Y10T29/49082Resistor making
    • Y10T29/49101Applying terminal
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T29/00Metal working
    • Y10T29/49Method of mechanical manufacture
    • Y10T29/49002Electrical device making
    • Y10T29/49105Switch making

Definitions

  • circuit interrupters of this type the current being controlled usually passes through the bimetallic element in whole or in part, for heating and actuating the same, preferably with a snap action, to interrupt the circuit when the current reaches a predetermined high value.
  • the lowest current to which these bimetallic elements will respond is a function of the watts it is possible to dissipate in the bimetal element itself in order to heat it to its circuit interrupting temperature.
  • bimetallic elements ofthe highest presently known specific resistances it-is still diiiicult to obtain positive circuit interrupting action below amperes, and even in some'cases l0 amperes. In such circuit interrupters a compromise mustl be made between the resistance and other electrical characteristicfs and the deection and snap characteristics of the. bimetallic elements with the result that most beneiicial results cannot be obtained.
  • the principal object of this invention is to provide an improved circuit interrupter using a bimetallic element, wherein positive circuit interruption may be obtained at low current values, evenas low as 1A; ampere, wherein maximum deliection and snap characteristics may be utilized ⁇ in the bimetallic elementl without substantial regard to the electrical characteristics thereof, which is rugged in construction and foolproof in operation, and which may be inexpensively manufactured.
  • the low amperage circuit interrupter of this invention includes a. deflecting bimetallic element having optimum desired deflection and/or snapping characteristics.
  • a thin electrical insulating film is bonded throughout its area to one side of the bimetallic element and a thin metallic film is bonded throughout its area to the electrical insulating film, the metallic film being electricallyV insulated fromi the bimetallic element by the electricalv insulating film.
  • the insul-ating film ⁇ and they metallic lilm uniformly deflect with the bimetallic element. Electric current is passed through. the metallic film and because of its thinness operates. to generate heat therein, the amount of heat being determined by the composition and cross-sectional area of the film.
  • the circuit interrupter acts as a compact unit with the mechanical characteristics being determined by the bimetallic element and the ⁇ electrical characteristics by the metallic film, each of which may be independently selected for desired overall operations.
  • Fig. l is a vertical sectional view through one form of the low amperage circuit interrupter of this invention.
  • Fig. 2 is a horizontal sectional view taken substantially along the line 2-2 of Fig. l;
  • Fig. 3 is an enlarged vertical sectional view taken substantially along the line 3-3 of Fig. 2;
  • Fig. 4 is a vertical sectional view through another form of the low amperage circuit interrupter of this invention.
  • Fig. 5 is a horizontal sectional view taken substantially along the line 5-5 of Fig. 4;
  • Fig. 6 is an enlarged vertical sectional view taken substantially along the line 6--6 of Fig. 5;
  • Fig. 7 is a vertical sectional view through another form of the low amperage circuit interrupter of this invention.
  • Fig. 8 is a bottom View of the circuit interrupter of Fig. 7;
  • Fig. 9 is an enlarged vertical sectional view taken substantially along the line 9 9 of Fig. 8.
  • One form of the low amperage circuit interrupter of this invention is generally designated at 10 in Figs. I, 2 and 3. It includes a base 11 of suitable electrical insulating material. Stationary contacts 12 and 13 are secured in spaced apartV relation on the base 11 by studs itand 15 and nuts 16 and 17. Secured on the base 11 is a support 19 having a head 20. A bimetallic element 21 is carried by the support 19 and is' urged against the headl 20 by a spring' 22 interposed between the base 11 and the bimetallic element 21.
  • the bimetallic element 21 is formed of two metal strips suitably secured together as by welding.
  • One of the metal strips 24 has a relatively low thermal coefiicient of expansion and the other metal strip 25 has arelatively high thermal coefficient of expansion.
  • the metal portion 24 may be formed of Invar or the like and the other metallic portion 25 may be formed of brass, Copper, or nickel, chromiumv or iron alloys and the like.
  • the bimetallic element 21 is mechanically stressed or deformed as illustrated in Figs. l. and 2, this being the normal or on position of the bimetallic element.
  • the bimetallic element 21 When, however, the bimetallic element 21 is heated, the mechanical stressing is overcome and the bimetallic element snaps to an off position wherein the ends of the bimetallic element are elevated or raised with a snap action.
  • the metals in the bimetallic element and their thickness and configuration are selected and arranged to provide the desiredv deiiection and snapping characteristics.
  • An electrical ⁇ insulating film 26 is bonded throughout its area to one side of the bimetallic element 21, preferably the high expansion side 25.
  • This electrical insulating film 26 may be formed of any suitable material which may be bonded to the bimetallic element.
  • One material which provides excellent results is polytetratiuoroethylene (Teiion).
  • the lm 26 is preferably preformed and is bonded to the bimetallic element 21 by heat sealing or by using a high temperature flexible cement.
  • This electrical insulating film is made quite thin, for example, having a thickness of about .001 or .O02 inch. Bonded throughout its area to the electrical insulating film; 26 is av thin metallic film 27.
  • This metallic film may be formed of any suitable metal, chrome or nickel providing excellent results.
  • Electric current is passed through this metallic film and the resistance of this filmlv to the flow of current operates to generate heat in the film.
  • a thin metallic lilm it is preferably coated on and bonded to the electrical insulating lmby an evaporated metal process.
  • the metallic film 27 is preferably coated on and bonded to the electrical insulating lmby an evaporated metal process.
  • the metallic film 27 it is preferable toy bond to the electrical e j 2,800,555 4 f" insulating film 26 before the latter is bonded to the bimetallic element 21.
  • the thickness of the metallic film 27 is dependent upon the electrical characteristics and the amount of heat that it is desired to generate for a given current fiow and by using the evaporated metal process this metallic film may be made extremely thin, as low as .0000020 inch thick.
  • the electrical insulating film 26 operates to electrically insulate the metallic film 27 from the bimetallic element 21 Vand yet it operates to provide good heat transfer for conducting heat from the metallic film 27 to the bimetallic element 21.
  • the bimetallic element 21 carries a pair of contacts 29 and 30 which are adapted to normally engage the stationary contacts 12 and 13 when the bimetallic element 21 is in the normal or on position.
  • the contacts 29 and 30 are riveted to the bimetallic element 21 as indicated at 31 in Fig. 3 and the contacts are electrically insulated from the bimetallic element 21 by electrical insulating Washers 32.
  • the contacts 29 and 30 are electrically co-nnected to the metallic film 27.
  • a layer of electrically conductive metal 33 is interposed between the contacts 29 and 30 and the metallic film 27.
  • This layer of metal 33 may, for example, be formed from silver paints such as are used for printed circuit Work.
  • the metal layers 33 operate to prevent extreme concentration of the current in the metallic film 27 adjacent the contacts 29 and 30. While both contacts 29 and 30 are illustrated in Figs. l, 2 and 3 as being electrically insulated from the bimetallic element 21, this is not necessary. So long as one of the contacts is so electrically insulated it is not necessary for the other one to be, since in either event, current can flow only through the metallic film 27 In the operation of the low amperage circuit interrupter as illustrated in Figs.
  • the contacts 29 and 30 normally engage the contacts 12 and 13.
  • Current flows only through the metallic film 27. If the current should become excessive, the metallic film 27 generates heat which is conducted through the electrical insulating film 26 to the bimetallic element 21.
  • the bimetallic element 21 When the bimetallic element 21 is heated to a predetermined value by the conducted heat, it snaps to the off position for separating the contacts 29 and 30 from the contacts 12 and 13 and thereby interrupts the circuit.
  • the bimetallic element 21 may be so constructed as to automatically reclose the contacts 29 and 30 against the contacts 12 and 13 or it may be so designed to maintain the contacts separated until such time as they are mechanically reset.
  • the former arrangement is particularly useful as an automatic reclosing circuit breaker, as a flasher for advertising signs or the like, or as a flasher for automatic directional signals or the like.
  • the latter arrangement is particularly useful as a circuit breaker which must be manually reset.
  • Another form of the low amperage circuit interrupter is generally designated at 35 in Figs. 4, 5 and 6. It includes a base 36 of electrical insulating material which carries a contact 37 by means of a stud 38 and a nut 39. A terminal 40 is secured to the base 36 in spaced relation from the contact 37 by a stud 41 and a nut 42. One end of a bimetallic element 44 is riveted to the stud 40 as indicated at 45 and here the terminal 40 is electrically insulated from the bimetallic element 44 by an insulating Washer 46. The other end of the bimetallic element 44 carries a contact 48 Which is adapted to engage the stationary contact 37.
  • the bimetallic element 44 includes metals 24 and 25 of different thermal coefficients of expansion, an electrical insulating Elm 26 and a metallic film 27.
  • the bimetallic element 44 may also be mechanically stressed to provide a snap action for engaging and separating the contacts 37 and 48 with a snap action.
  • the metallic film 27 is electrically connected to the terminal 40 and the contact 48 by metallic layers 33.
  • insulating the bimetallic element from the terminal 40 it may be insulated from the contact 48 in the manner described above in connection with Figs. 1 to 3.
  • the circuit interrupter 35 of Figs. 4 to 6 operates in substantially the same manner as the circuit interrupter 10 of Figs. l to 3 and, therefore, a further description is not considered necessary.
  • the circuit interrupter generally designated at 50 in l Figs. 7 to 9 is in the form of a telephone grasshopper fuse.
  • the base 51 which may be formed of nickel silver or the like.
  • One end of the base 51 is cased with an electrical insulating sleeve 52.
  • a terminal 53 Over this sleeve 52 is mounted a terminal 53, the terminal 53 being electrically insulated from the base 51 by the electrical insulating sleeve 52.
  • the base 51and terminal 53 is provided with a slot 54 for mounting the same in a panel.
  • the terminal 53 is provided with an extension 55 which in turn carries a stationary contact 56.
  • a bimetallic element 58 is secured to the underside of the base 51 as by Welding indicated at 59.
  • the bimetallic element 58 includes metals 24 and 25 of different thermal coefiicients of expansion, a layer 26 of electrical insulating material and a metallic film 27.
  • the bimetallic element 58 When the bimetallic element 58 is Welded to the base 51, the electrical insulating film 26 is destroyed at the Weld points so that the bimetallic element 58 and the metallic film 27 are both electrically connected to the metallic base 51.
  • the base 51 and bimetallic element 58 are provided with a slot 60 also for mounting the circuit interrupter in a panel.
  • the outer end of the bimetallic element 58 carries a contact 61 which is adapted normally to engage the contact 56.
  • This contact 61 is secured to the bimetallic element 58 as by riveting indicated at 62 and is electrically insulated therefrom by an insulating washer 63.
  • the manner of operation of the circuit interrupter 50 is very much like that described above in connection with the circuit interrupters 10 and 35.
  • the circuit from the base 51 to the contact 56 extends only through the metallic film 27 and the contact 61 so as to generate heat in the metallic film 26 to the bimetallic element 58.
  • the bimetallic element 58 is sufficiently heated, it moves the contact 61 away from the contact 56 to interrupt that circuit.
  • the end 65 of the bimetallic element 58 may contact a bus bar 66 for completing an auxiliary circuit from the base 51 to the bus bar 66.
  • This auxiliary circuit may form a portion of an alarm circuit for indicating opening or separating of the contacts 56 and 61.
  • the deflection and/or snapping characteristics of the bimetallic element may be determined independently from the electrical characteristics, the electrical characteristics being determined by the metallic film. These various characteristics may be independently selected so as to obtain any desired overall operation of the circuit interrupter. Thus it is possible to provide a circuit interrupter having desired mechanical characteristics and still be able to successfully interrupt low current circuits, even as low as 1A ampere currents.
  • a low amperage circuit interrupter comprising a deflecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film elements, and means including contact means operated by the bimetallic element for passing an electric eurrent through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same.
  • a low amperage circuit interrupter comprising a deflecting bimetallic element having high and low thermal expansion sides, an electrical insulating film bonded throughout its area to the high expansion side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including contact means operated by the bimetallic element for passing an electric current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same.
  • a low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including a stationary Contact and a contact carried by the bimetallic element normally engaging the stationary contact but electrically insulated from the bimetallic element and electrically connected to the metallic film for passing electrical current through the metallic film under the control of the contacts for heating the metallic film, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same to separate the contacts upon the occurrence of excessive current conditions.
  • a low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly deflecting with said metallic elements, a contact member secured to the bimetallic element but electrically insulated therefrom, a metallic layer bonded to the metallic film about the contact mem' ber and engaging the contact member for electrically connecting the contact member to the metallic film, and means including the contact member and metallic layer for passing electrical current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for deflecting the same.
  • a low amperage circuit interrupter comprising a deflecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including a contact member secured to the bimetallic element but electrically insulated ⁇ from the bimetallic element and electrically connected to the metallic film for passing electric current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for deflecting the same.
  • a low amperage circuit interrupter comprising a mechanically stressed deflecting bimetallic element having a normal on position and moved with a snap action to an off position when heated to a predetermined value
  • a low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, a stationary contact, a contact carried by the bimetallic element and normally engaging the stationary contact and disengaging the stationary contact when the bimetallic element is heated to a predetermined value, and means including said contacts for passing an electric current through the metallic film for heating the same while the contacts engage each other, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to move to a position for separating the contacts.
  • a low amperage circuit interrupter comprising an electrical insulating base, a defiecting bimetallic ele.-V ment, means mounting the bimetallic element at its center to the base, said bimetallic element being mechanically stressed and having a normal on position and movable with a snap action to an off position when heated to a predetermined value, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly deflecting with said metallic elements, a pair of stationary contacts carried by the base, a pair of contacts carried by the bimetallic element and engaging the stationary contacts when the bimetallic elea ment is in the on position and disengaging the stationary contacts when the bimetallic element is in the of position,
  • said contacts carried by the bimetallic element being electrically connected to the metallic film and at least one of said contacts being electrically insulated from the bimetallic element, and means including said contacts for passing an electric current through the metallic lrn for heating the same when the contacts engage each other, the heat from themetallic lm being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to snap to the oi position.

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Description

.fuly 23, 1957 E. v. suNDT 2,800,555
LOW AMPERAGE CIRCUIT INTERRUPTER Filed Aug. 18, 1954 E y 54 5:5 55 y @i United States Patent() Low AMPERAGE CIRCUIT INTERRUPTER Edward V. Sundt, Wilmette, Ill., assigner to Sundt Engineering Company, Des Plaines, Ill., a corporation of Illinois Application August 18, 1954, Serial No. 450,760
9 Claims. (Cl. 20G-122) This invention relatesl to circuit interrupters which utilize bimetallic elements as the actuating means therefor.
In circuit interrupters of this type the current being controlled usually passes through the bimetallic element in whole or in part, for heating and actuating the same, preferably with a snap action, to interrupt the circuit when the current reaches a predetermined high value. The lowest current to which these bimetallic elements will respond is a function of the watts it is possible to dissipate in the bimetal element itself in order to heat it to its circuit interrupting temperature. Even using bimetallic elements ofthe highest presently known specific resistances, it-is still diiiicult to obtain positive circuit interrupting action below amperes, and even in some'cases l0 amperes. In such circuit interrupters a compromise mustl be made between the resistance and other electrical characteristicfs and the deection and snap characteristics of the. bimetallic elements with the result that most beneiicial results cannot be obtained.
The principal object of this invention is to provide an improved circuit interrupter using a bimetallic element, wherein positive circuit interruption may be obtained at low current values, evenas low as 1A; ampere, wherein maximum deliection and snap characteristics may be utilized` in the bimetallic elementl without substantial regard to the electrical characteristics thereof, which is rugged in construction and foolproof in operation, and which may be inexpensively manufactured.
Briefly., the low amperage circuit interrupter of this invention. includes a. deflecting bimetallic element having optimum desired deflection and/or snapping characteristics. A thin electrical insulating film is bonded throughout its area to one side of the bimetallic element and a thin metallic film is bonded throughout its area to the electrical insulating film, the metallic film being electricallyV insulated fromi the bimetallic element by the electricalv insulating film. The insul-ating film` and they metallic lilm uniformly deflect with the bimetallic element. Electric current is passed through. the metallic film and because of its thinness operates. to generate heat therein, the amount of heat being determined by the composition and cross-sectional area of the film. This heat is conducted' through the thin electrical insulating film to the bimetallic element for deliecting. the latter in accordance with its deiiecting. and/or snapping characteristics. As a result the circuit interrupter acts as a compact unit with the mechanical characteristics being determined by the bimetallic element and the` electrical characteristics by the metallic film, each of which may be independently selected for desired overall operations.
Further objects of this invention reside in the details of construction of the low amperage circuit interrupter and inthe cooperative relationships between the component partsthereof.
Other objects andy advantages of this invention will become apparent to those skilledv in the art upon reference.
ICC
to the accompanying specification, claims and drawing in which:
Fig. l is a vertical sectional view through one form of the low amperage circuit interrupter of this invention;
Fig. 2 is a horizontal sectional view taken substantially along the line 2-2 of Fig. l;
Fig. 3 is an enlarged vertical sectional view taken substantially along the line 3-3 of Fig. 2;
Fig. 4 is a vertical sectional view through another form of the low amperage circuit interrupter of this invention;
Fig. 5 is a horizontal sectional view taken substantially along the line 5-5 of Fig. 4;
Fig. 6 is an enlarged vertical sectional view taken substantially along the line 6--6 of Fig. 5;
Fig. 7 is a vertical sectional view through another form of the low amperage circuit interrupter of this invention;
Fig. 8 is a bottom View of the circuit interrupter of Fig. 7;
Fig. 9 is an enlarged vertical sectional view taken substantially along the line 9 9 of Fig. 8.
One form of the low amperage circuit interrupter of this invention is generally designated at 10 in Figs. I, 2 and 3. It includes a base 11 of suitable electrical insulating material. Stationary contacts 12 and 13 are secured in spaced apartV relation on the base 11 by studs itand 15 and nuts 16 and 17. Secured on the base 11 is a support 19 having a head 20. A bimetallic element 21 is carried by the support 19 and is' urged against the headl 20 by a spring' 22 interposed between the base 11 and the bimetallic element 21.
The bimetallic element 21 is formed of two metal strips suitably secured together as by welding. One of the metal strips 24 has a relatively low thermal coefiicient of expansion and the other metal strip 25 has arelatively high thermal coefficient of expansion. For example, the metal portion 24 may be formed of Invar or the like and the other metallic portion 25 may be formed of brass, Copper, or nickel, chromiumv or iron alloys and the like. To provide a snap acting action the bimetallic element 21 is mechanically stressed or deformed as illustrated in Figs. l. and 2, this being the normal or on position of the bimetallic element. When, however, the bimetallic element 21 is heated, the mechanical stressing is overcome and the bimetallic element snaps to an off position wherein the ends of the bimetallic element are elevated or raised with a snap action. The metals in the bimetallic element and their thickness and configuration are selected and arranged to provide the desiredv deiiection and snapping characteristics.
An electrical` insulating film 26 is bonded throughout its area to one side of the bimetallic element 21, preferably the high expansion side 25. This electrical insulating film 26 may be formed of any suitable material which may be bonded to the bimetallic element. One material which provides excellent results is polytetratiuoroethylene (Teiion). The lm 26 is preferably preformed and is bonded to the bimetallic element 21 by heat sealing or by using a high temperature flexible cement. This electrical insulating film is made quite thin, for example, having a thickness of about .001 or .O02 inch. Bonded throughout its area to the electrical insulating film; 26 is av thin metallic film 27. This metallic film may be formed of any suitable metal, chrome or nickel providing excellent results. Electric current is passed through this metallic film and the resistance of this filmlv to the flow of current operates to generate heat in the film. In* order to obtain a thin metallic lilm it is preferably coated on and bonded to the electrical insulating lmby an evaporated metal process. For production reasons it is preferable toy bond the metallic film 27 tothe electrical e j 2,800,555 4 f" insulating film 26 before the latter is bonded to the bimetallic element 21. The thickness of the metallic film 27 is dependent upon the electrical characteristics and the amount of heat that it is desired to generate for a given current fiow and by using the evaporated metal process this metallic film may be made extremely thin, as low as .0000020 inch thick. The electrical insulating film 26 operates to electrically insulate the metallic film 27 from the bimetallic element 21 Vand yet it operates to provide good heat transfer for conducting heat from the metallic film 27 to the bimetallic element 21.
The bimetallic element 21 carries a pair of contacts 29 and 30 which are adapted to normally engage the stationary contacts 12 and 13 when the bimetallic element 21 is in the normal or on position. The contacts 29 and 30 are riveted to the bimetallic element 21 as indicated at 31 in Fig. 3 and the contacts are electrically insulated from the bimetallic element 21 by electrical insulating Washers 32. However, the contacts 29 and 30 are electrically co-nnected to the metallic film 27. Thus, when the circuit interrupter is closed as illustrated in Fig. l electrical current passes from the contact 30 to the contact 29 through the metallic film 27 only and not through the bimetallic element 21. Because the metallic film 27 is very thin and in order to distribute the current flow through the metallic film 27, a layer of electrically conductive metal 33 is interposed between the contacts 29 and 30 and the metallic film 27. This layer of metal 33 may, for example, be formed from silver paints such as are used for printed circuit Work. The metal layers 33 operate to prevent extreme concentration of the current in the metallic film 27 adjacent the contacts 29 and 30. While both contacts 29 and 30 are illustrated in Figs. l, 2 and 3 as being electrically insulated from the bimetallic element 21, this is not necessary. So long as one of the contacts is so electrically insulated it is not necessary for the other one to be, since in either event, current can flow only through the metallic film 27 In the operation of the low amperage circuit interrupter as illustrated in Figs. l, 2 and 3 the contacts 29 and 30 normally engage the contacts 12 and 13. Current flows only through the metallic film 27. If the current should become excessive, the metallic film 27 generates heat which is conducted through the electrical insulating film 26 to the bimetallic element 21. When the bimetallic element 21 is heated to a predetermined value by the conducted heat, it snaps to the off position for separating the contacts 29 and 30 from the contacts 12 and 13 and thereby interrupts the circuit. When the circuit is so interrupted the generation of the heat in the metallic film 27 is interrupted and the bimetallic element cools down. The bimetallic element 21 may be so constructed as to automatically reclose the contacts 29 and 30 against the contacts 12 and 13 or it may be so designed to maintain the contacts separated until such time as they are mechanically reset. The former arrangement is particularly useful as an automatic reclosing circuit breaker, as a flasher for advertising signs or the like, or as a flasher for automatic directional signals or the like. The latter arrangement is particularly useful as a circuit breaker which must be manually reset.
Another form of the low amperage circuit interrupter is generally designated at 35 in Figs. 4, 5 and 6. It includes a base 36 of electrical insulating material which carries a contact 37 by means of a stud 38 and a nut 39. A terminal 40 is secured to the base 36 in spaced relation from the contact 37 by a stud 41 and a nut 42. One end of a bimetallic element 44 is riveted to the stud 40 as indicated at 45 and here the terminal 40 is electrically insulated from the bimetallic element 44 by an insulating Washer 46. The other end of the bimetallic element 44 carries a contact 48 Which is adapted to engage the stationary contact 37. The bimetallic element 44 includes metals 24 and 25 of different thermal coefficients of expansion, an electrical insulating Elm 26 and a metallic film 27.
If desired, the bimetallic element 44 may also be mechanically stressed to provide a snap action for engaging and separating the contacts 37 and 48 with a snap action. Here also, the metallic film 27 is electrically connected to the terminal 40 and the contact 48 by metallic layers 33. Instead of insulating the bimetallic element from the terminal 40 it may be insulated from the contact 48 in the manner described above in connection with Figs. 1 to 3. The circuit interrupter 35 of Figs. 4 to 6 operates in substantially the same manner as the circuit interrupter 10 of Figs. l to 3 and, therefore, a further description is not considered necessary.
The circuit interrupter generally designated at 50 in l Figs. 7 to 9 is in the form of a telephone grasshopper fuse.
It includes a base 51 which may be formed of nickel silver or the like. One end of the base 51 is cased with an electrical insulating sleeve 52. Over this sleeve 52 is mounted a terminal 53, the terminal 53 being electrically insulated from the base 51 by the electrical insulating sleeve 52. The base 51and terminal 53 is provided with a slot 54 for mounting the same in a panel. The terminal 53 is provided with an extension 55 which in turn carries a stationary contact 56. A bimetallic element 58 is secured to the underside of the base 51 as by Welding indicated at 59. The bimetallic element 58 includes metals 24 and 25 of different thermal coefiicients of expansion, a layer 26 of electrical insulating material and a metallic film 27. When the bimetallic element 58 is Welded to the base 51, the electrical insulating film 26 is destroyed at the Weld points so that the bimetallic element 58 and the metallic film 27 are both electrically connected to the metallic base 51. The base 51 and bimetallic element 58 are provided with a slot 60 also for mounting the circuit interrupter in a panel.
The outer end of the bimetallic element 58 carries a contact 61 which is adapted normally to engage the contact 56. This contact 61 is secured to the bimetallic element 58 as by riveting indicated at 62 and is electrically insulated therefrom by an insulating washer 63. The manner of operation of the circuit interrupter 50 is very much like that described above in connection with the circuit interrupters 10 and 35. Here the circuit from the base 51 to the contact 56 extends only through the metallic film 27 and the contact 61 so as to generate heat in the metallic film 26 to the bimetallic element 58. When the bimetallic element 58 is sufficiently heated, it moves the contact 61 away from the contact 56 to interrupt that circuit. At the same time, the end 65 of the bimetallic element 58 may contact a bus bar 66 for completing an auxiliary circuit from the base 51 to the bus bar 66. This auxiliary circuit may form a portion of an alarm circuit for indicating opening or separating of the contacts 56 and 61.
In all forms of this invention the deflection and/or snapping characteristics of the bimetallic element may be determined independently from the electrical characteristics, the electrical characteristics being determined by the metallic film. These various characteristics may be independently selected so as to obtain any desired overall operation of the circuit interrupter. Thus it is possible to provide a circuit interrupter having desired mechanical characteristics and still be able to successfully interrupt low current circuits, even as low as 1A ampere currents.
While for purposes of illustration several forms of this invention have been disclosed other forms thereof may become apparent to those skilled in the art upon reference to this disclosure and, therefore, this invention is to be limited only by the scope of the appended claims.
I claim as my invention:
1. A low amperage circuit interrupter comprising a deflecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film elements, and means including contact means operated by the bimetallic element for passing an electric eurrent through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same.
2. A low amperage circuit interrupter comprising a deflecting bimetallic element having high and low thermal expansion sides, an electrical insulating film bonded throughout its area to the high expansion side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including contact means operated by the bimetallic element for passing an electric current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same.
3. A low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including a stationary Contact and a contact carried by the bimetallic element normally engaging the stationary contact but electrically insulated from the bimetallic element and electrically connected to the metallic film for passing electrical current through the metallic film under the control of the contacts for heating the metallic film, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for defiecting the same to separate the contacts upon the occurrence of excessive current conditions.
4. A low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly deflecting with said metallic elements, a contact member secured to the bimetallic element but electrically insulated therefrom, a metallic layer bonded to the metallic film about the contact mem' ber and engaging the contact member for electrically connecting the contact member to the metallic film, and means including the contact member and metallic layer for passing electrical current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for deflecting the same.
5, A low amperage circuit interrupter comprising a deflecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, and means including a contact member secured to the bimetallic element but electrically insulated` from the bimetallic element and electrically connected to the metallic film for passing electric current through the metallic film for heating the same, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for deflecting the same.
6. A low amperage circuit interrupter comprising a mechanically stressed deflecting bimetallic element having a normal on position and moved with a snap action to an off position when heated to a predetermined value,
an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulatedthereby from the bimetallic c element, said insulating film and metallic film uniformly deflecting with said metallic elements, a stationary contact, a contact carried by the bimetallic element and engaging the stationary contact when the bimetalic ele-- ment is in the on position and disengaging the stationary contact when the bimetallic element is in the off position, and means including said contacts for passing an electric current through the metallic film for heating the same while the contacts engage each other, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to snap to the off position.
7. A low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly defiecting with said metallic elements, a stationary contact, a contact carried by the bimetallic element and normally engaging the stationary contact and disengaging the stationary contact when the bimetallic element is heated to a predetermined value, and means including said contacts for passing an electric current through the metallic film for heating the same while the contacts engage each other, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to move to a position for separating the contacts.
8. A low amperage circuit interrupter comprising a defiecting bimetallic element, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly deflecting with said metallic elements, a stationary contact, a contact carried by the bimetallic element and normally engaging the stationary contact and disengaging the stationary contact when the bimetallic element is heated to a predetermined value, and means including said contacts for passing an electric current through the metallic film for heating the same while the contacts engage each other, the heat from the metallic film being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to move to a position for separating the contacts, a second stationary contact engaged by the bi= metallic element when the bimetallic element is moved to separate said first mentioned contacts, and means in.- cluding the bimetallic element and the second stationary Contact for completing an auxiliary electric circuit when the bimetallic element engages the second stationary contact. l
9. A low amperage circuit interrupter comprising an electrical insulating base, a defiecting bimetallic ele.-V ment, means mounting the bimetallic element at its center to the base, said bimetallic element being mechanically stressed and having a normal on position and movable with a snap action to an off position when heated to a predetermined value, an electrical insulating film bonded throughout its area to one side of the bimetallic element, a metallic film bonded throughout its area to the electrical insulating film and electrically insulated thereby from the bimetallic element, said insulating film and metallic film uniformly deflecting with said metallic elements, a pair of stationary contacts carried by the base, a pair of contacts carried by the bimetallic element and engaging the stationary contacts when the bimetallic elea ment is in the on position and disengaging the stationary contacts when the bimetallic element is in the of position,
said contacts carried by the bimetallic element being electrically connected to the metallic film and at least one of said contacts being electrically insulated from the bimetallic element, and means including said contacts for passing an electric current through the metallic lrn for heating the same when the contacts engage each other, the heat from themetallic lm being conducted through the electrical insulating film to the bimetallic element for heating the same to cause it to snap to the oi position.
References Cited in the file of this patent UNITED STATES PATENTS 2,011,610 Bletz Aug. 20, 1935 8 Immel'et al Nov. 1l, 1941 Swingle Aug. 18, 1942 Willmann Apr. 18, 1944 Shively et al Apr. 25, 1944 Cataldo Apr. 21, 1953 FOREIGN PATENTS Great Britain Aug. 23, 1948
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US2920165A (en) * 1956-08-09 1960-01-05 Servel Inc Flasher switch mechanism
US3203166A (en) * 1961-09-08 1965-08-31 Texas Instruments Inc Thermostatic elements
US3248501A (en) * 1962-07-05 1966-04-26 Therm O Disc Inc Thermostatic control having electrically insulated heater element
US3274359A (en) * 1963-12-30 1966-09-20 Mc Graw Edison Co Thermal relay
US3291935A (en) * 1963-09-25 1966-12-13 Cornelius B Murphy Thermostat actuators of resinous material
US3344250A (en) * 1967-09-26 Means and method for making electri- cal connections including weld pro- jection means at the distal end sur- face of the shank
US3361883A (en) * 1966-11-01 1968-01-02 Theodore Brassard Jr. Calibrated thermostatic switch and method for calibrating the same including welded lug and recess means
US4115750A (en) * 1973-10-10 1978-09-19 Amp Incorporated Bimetal actuator
US4754920A (en) * 1986-11-28 1988-07-05 Hamilton Standard Controls, Inc. Compact operator for gas control valves
US20110025449A1 (en) * 2009-08-01 2011-02-03 Stefan Grosskopf Bi-metal snap action disc
US20150279596A1 (en) * 2014-03-27 2015-10-01 Tyco Electronics Japan G.K. Insulated Thermal Cut-Off Device

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US2011610A (en) * 1934-09-13 1935-08-20 Westinghouse Electric & Mfg Co Thermal switch
US2262397A (en) * 1940-01-24 1941-11-11 Westinghouse Electric & Mfg Co Circuit interrupter
US2293179A (en) * 1941-02-26 1942-08-18 Westinghouse Electric & Mfg Co Circuit breaker
US2347014A (en) * 1937-09-24 1944-04-18 Westinghouse Electric & Mfg Co Thermal switching device
US2347514A (en) * 1940-05-04 1944-04-25 Telephone Answering And Record Control method and apparatus
GB606894A (en) * 1946-06-18 1948-08-23 Alexander Frederic Fekete Improvements in or relating to electric heating
US2636098A (en) * 1950-05-01 1953-04-21 Pierce John B Foundation Thermostatic switch

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Publication number Priority date Publication date Assignee Title
US2011610A (en) * 1934-09-13 1935-08-20 Westinghouse Electric & Mfg Co Thermal switch
US2347014A (en) * 1937-09-24 1944-04-18 Westinghouse Electric & Mfg Co Thermal switching device
US2262397A (en) * 1940-01-24 1941-11-11 Westinghouse Electric & Mfg Co Circuit interrupter
US2347514A (en) * 1940-05-04 1944-04-25 Telephone Answering And Record Control method and apparatus
US2293179A (en) * 1941-02-26 1942-08-18 Westinghouse Electric & Mfg Co Circuit breaker
GB606894A (en) * 1946-06-18 1948-08-23 Alexander Frederic Fekete Improvements in or relating to electric heating
US2636098A (en) * 1950-05-01 1953-04-21 Pierce John B Foundation Thermostatic switch

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3344250A (en) * 1967-09-26 Means and method for making electri- cal connections including weld pro- jection means at the distal end sur- face of the shank
US2920165A (en) * 1956-08-09 1960-01-05 Servel Inc Flasher switch mechanism
US3203166A (en) * 1961-09-08 1965-08-31 Texas Instruments Inc Thermostatic elements
US3248501A (en) * 1962-07-05 1966-04-26 Therm O Disc Inc Thermostatic control having electrically insulated heater element
US3291935A (en) * 1963-09-25 1966-12-13 Cornelius B Murphy Thermostat actuators of resinous material
US3274359A (en) * 1963-12-30 1966-09-20 Mc Graw Edison Co Thermal relay
US3361883A (en) * 1966-11-01 1968-01-02 Theodore Brassard Jr. Calibrated thermostatic switch and method for calibrating the same including welded lug and recess means
US4115750A (en) * 1973-10-10 1978-09-19 Amp Incorporated Bimetal actuator
US4754920A (en) * 1986-11-28 1988-07-05 Hamilton Standard Controls, Inc. Compact operator for gas control valves
US20110025449A1 (en) * 2009-08-01 2011-02-03 Stefan Grosskopf Bi-metal snap action disc
EP2282320A1 (en) * 2009-08-01 2011-02-09 Limitor GmbH Bimetallic snap disc
US20150279596A1 (en) * 2014-03-27 2015-10-01 Tyco Electronics Japan G.K. Insulated Thermal Cut-Off Device
US9831054B2 (en) * 2014-03-27 2017-11-28 Littelfuse, Inc. Insulated thermal cut-off device

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