US2877144A - Vitreous coated magnetic material - Google Patents
Vitreous coated magnetic material Download PDFInfo
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- US2877144A US2877144A US430841A US43084154A US2877144A US 2877144 A US2877144 A US 2877144A US 430841 A US430841 A US 430841A US 43084154 A US43084154 A US 43084154A US 2877144 A US2877144 A US 2877144A
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F1/00—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties
- H01F1/01—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials
- H01F1/03—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity
- H01F1/0302—Magnets or magnetic bodies characterised by the magnetic materials therefor; Selection of materials for their magnetic properties of inorganic materials characterised by their coercivity characterised by unspecified or heterogeneous hardness or specially adapted for magnetic hardness transitions
- H01F1/0311—Compounds
- H01F1/0313—Oxidic compounds
- H01F1/0315—Ferrites
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- C—CHEMISTRY; METALLURGY
- C23—COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
- C23D—ENAMELLING OF, OR APPLYING A VITREOUS LAYER TO, METALS
- C23D5/00—Coating with enamels or vitreous layers
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- Y—GENERAL 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
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S428/00—Stock material or miscellaneous articles
- Y10S428/90—Magnetic feature
-
- Y—GENERAL 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
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10T—TECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
- Y10T428/00—Stock material or miscellaneous articles
- Y10T428/24—Structurally defined web or sheet [e.g., overall dimension, etc.]
- Y10T428/24942—Structurally defined web or sheet [e.g., overall dimension, etc.] including components having same physical characteristic in differing degree
Definitions
- This invention relates to hermetically-sealed ferromagnetic dielectric materials and a method for sealing the same, and more particularly to vitreous-coated ferromagnetic dielectric compacts and a method for applying a vitreous coat to such materials.
- Ferromagnetic dielectric materials known in the art simply as ferrites, are crystalline ceramics in which the major constituent is iron oxide. These ceramics are generally formed into a compact by a closel'yacontrolled sin-' tering process from a powder mixture which includes a plurality of bivalent-metal oxides. Ferrite compacts have a wide range of physical and electrical properties which are dependent on their composition and the sintering technique employed in their formation.
- the ferromagnetic dielectrics are particularly useful in microwave applications because at these frequencies they exhibit a characteristic known as the Faraday effect. However, in use, the heating efiect, power factor, and
- the'ferrites arefalso useful in certain types of electron discharge devices such as, for example, the traveling wave type;
- the susceptibility of the ferrites to release occluded gases over a long period of time is an impediment to: this type of use because of the necessary high vacuum which'must be maintained in the electron discharge device.
- thisproblem can be obviated by hermetically sealingthe ferrite compact inaccorda'nce with the present invention. Accordingly, it follows that if the ferrite compacts can be hermetically sealed in an envelope or skinin a dry condition, their usefulness will .be very much enhanced.
- the manner in which thev ferrites are utilized, as well as their inherent physical properties interposes a number of difiiculties in the way of achieving a's'atisfactory hermetic envelope.
- a sealing skin for the compact must be capableyof withstanding at temperature of at least severalhundred degress centigrade ,without deterioration, cracking or otherwiserdeveloping porosity.
- the substances capable of The ferromagnetic dielectric compact or ferrite is im-f "ice performing a sealing function at these temperatures are the vitreous products, notably, glass.
- a further objective of this invention is to providev a method for applying a vitreous coating to ferromagnetic dielectric compacts.
- Fig. 1 is a partial broken section of a hermetically sealed ferromagnetic ferrite device of the present inven tion; and a Fig. 2 is an enlarged cross-sectional view, section 22.' of the device shown .in Fig. 1. p 7
- a typical embodiment of the present invention comprising an elongated ferrite compact or slug 10 having a. glass coating or skin 11 which hermetically seals the compact 10.,from the surrounding medium.
- the diameter of the middle portion of thecompact is of the order of from 0.1 to 1.0 inch and its length is generally within the range of from one to four inches, the dimensions being determined by the particular application.
- ferrites may be used in numerous other forms such as, for example, hollow or solid cylinder, it is readily apparent that the scope of the present: invention is not limited to the sizes mentioned or particu-- larfconfiguration shown. .7
- ferrites The mineral magnetite, FeOFe O is the well-known, ferro-ferrite occurring in nature.
- Past experiments have led to success in making synthetic ferrites with both soft" and permanent magnetic properties. Due to the absence of metal components and in view of their dense structure, ferrites have relatively high volume resistivity and high permeability-in comparison to powdered iron materials. Their specific gravity lies between4 and 5 and their dielectric constant is about 9.
- the thermal coefficient of expansion of ferrites is primarily limited to the range 71 to 93 inch per inch per C. They have a relatively high modulus of elasticity and their ultimate strength is usually about 10,000 p. s. i., i. e., pounds per square inch, in compression and 2000 p. s. i. in tension. These three physical properties are generally the most important when correlated with those of glass, the thermal expansion coefficient normallybeing the most important of the three.
- one type of useful glass hasv a working temperature of 560 C.
- the working temperature of a glass is to be distinguished from the softening temperature which may be as low as 440 C. and which is defined as being the temperature at which the glass becomes suificiently yielding "so that strains are relieved at an extremely rapid rate or within a. very short period, for example, less than one minute.
- the seal is then allowed to cool directly to room temperature or, as is the more usual case, the cooling process is temporarily arrested at a predetermined elevated temperature, termed the annealing" point or the lowest temperature below the softening temperature at which 90% of the internal stresses of the glass will be removed in about fifteen minutes.
- the glass formed in such a batch requires, for melting, temperatures of about 1700 C. which temperatures are too expensive and impractical to achieve even with the best commercial glass-furnace refractories. Also, the resultant glass is so viscous, even at melting temperatures, that it can be homogenized and shaped only with great difiiculty. Consequently, for fiuxing or lowering the melting temperature, some sodium, or potassium oxide, or both,
- stabilizing and modifying oxides such as type glasses, namely, borosilicate glass; and 96% silica.
- the glasses which are most useful in practicing the present invention are then the soft glasses, the sodalime glasses and the lead glasses.
- the thermal coeflicients C Although soft glasses may go lower to possibly 10"' inch per inch per C., few will go as high I as 140X10- inch per inch per C.
- Fused silica or silica glass has a coetficient of expansion which is too low for the present purposes, being about 5.5X10'- inch per inch per C. and 96% silica glass likewise has too low,a coefficient of expansion, being about 8 lO-' inch per inch per C.
- the glasses called borosilicate glasses contain 5% or more of boric oxide. They are also usually too hard to seal a ferrite, the range of their thermal expansion coefficients being about 13 to 60x10- inch per inch per C.
- Glass in general has an ultimate strength in compression and tension ranging respectively from 90,000 to. 180,000 and from 4,000 to 1,000,000 p. s. i.
- the soft glasses are generallysatisfactoryfor coating a ferrite
- glasses whichmay be used toaparticular advantage to reduce the riskz'of structural. failures during. the manufacture of. the seal. and especially: during the handlingof the component materials.
- ferrites having a thermal expansion coeflicient falling within the range 71 86 10' inch per inch per C. it has been an effective expansivity between 65 and l00 l0 inch per inch per C.
- a glass having characteristics approximating these is commonly known as lime glass.
- This glass is composed of 73.3% SiO 15.6% Na O; 5.4% CaO; 3.8% MgO; 1.4% R 0 0.5% K 0 and has an effective expansivity of 92i2 10- inch per inch per C., and a Youngs modulus of 98 l0-' p. s. i.
- a suitable glass of the above-described types is first powdered and then suspended in a liquid such as, for example, water, methyl alcohol, or a solution of nitrocellulose in amyl acetate. This suspension of powdered glass is then brushed or sprayed uniformly over the ferrite slug 10 or alternatively, the ferrite slug 10 may be immersed in a suspension of powdered glass in the solution of nitrocellulose in amyl acetate.
- the ferrite slug 10 covered with the suspension of powdered glass is then heated in a controlled atmosphere to the working temperature of the glass and then slowly cooled. This process is repeated until the glass coating 11 has a glaze finish and is of a suitable thickness.
- the thickness of glass coating 11 depending on the uses to which the ferrite is to be put is of the order of from 0.003 inch to more than 0.06 inch, the thinner coatings being used where permissible in that the electrical losses are less.
- glass coating 11 of the device has elongated pointed ends 12 where this, it is necessary for the electromagnetic wave to propagate through the medium of the device.
- dielectric constant of ferrite is quite high, there is generally an impedance mismatch between the medium surrounding the device and the medium of the ferrite slug-10.
- the glass has a dielectric constant approximately equal to the geometric mean of the dielectric constants of :the surrounding and ferrite mediums, it may be employed to substantially improve theimpedance match of the ferrite slug 10 to the surrounding medium.
- the thicknessof glass points 12 for optimum matching as. measured along the longitudinal axis of. the device is of the orde.
- ferrites of this type are sealed. by first applying a coatingof glass having a-high work-.
- This coating will generally not effectively seal the ferrite but it will prevent subsequent coatings of glass having a lower working temperature from being absorbed into the ferrite.
- this process of hermetically sealing a porous ferrite is as follows:
- Heat glass 0080 in an oven in air to its sintering temperature i. e., the temperature at which substantial fusion but not fluidity is indicated, e. g., 700800 C.
- Corning glass 7570 by itself has utility in the manufacture of the ferrite seal of the present invention in that its working temperature is 560 C. whereas most other glasses have a working temperature above 800 C. The use of this glass reduces the risk of structural failure due to the low thermal shock resistance of ferrites.
- Corning glasses 7570 and 0080 have thermal expansion coefficients of 84 and 92X 10- inch per inch per C., respectively, and in this regard are useful in preventing differential stresses. Youngs modulus of Corning 7570 is within the usual soft glass range. Likewise, Corning 0080 has a Youngs modulus of 98x10" p. s. i.
- a few other glasses may also be used to hermetically seal a ferrite material.
- these glasses are clear sealing glass which is designated by the present Corning number code by 8870. Its application is somewhat limited particularly because of its high dielectric constant, viz., 9.5; however, its thermal expansion coefiicient is 91 X 10- inch per inch per C. and a large advantage accompanying its employment is its modulus of elasticity, 76 10-" p. s. i., which is comparatively low.
- a device comprising an element composed of a porous ferromagnetic dielectric ceramic, said element having predetermined physical characteristics; a sintered layer of a first type of glass covering the exposed surface of said element, said first type of glass having a predetermined working temperature; and a coating of a second type of glass disposed on top of said sintered layer, the working temperature of said second type of glass being more than 80 C. lower than said predetermined working temperature, and said first and second types of glasses having thermal coefficients of expansion of from 65 to 120 X10 inch per inch per degree centigrade, whereby said first and second types of glass provide a seal having physical characteristics substantially equivalent to said predetermined physical characteristics of the ferrite element.
- the method of hermetically sealing a normally porous ferromagnetic dielectric compact employing first and second types of glasses having first and second predetermined softening temperatures, respectively, said first softening temperature being higher than said second softening temperature, said method including the steps of producing first and second liquid suspensions of said first and second types of glasses, respectively; applying said first liquid suspension to the surface of said compact; heating said compact to the fusing temperature of said first type of glass to produce a coating of said first type of glass on said compact that partially seals the surface thereof; applying said second liquid suspension to the coated surface of said compact; and heating said compact to a temperature not less than the softening temperature of said second type of glass and less than the softening temperature of said first type'of glass.
- a device comprising an element composed of a porous ferromagnetic dielectric ceramic, said element having predetermined physical characteristics; a sintered layer of a first type of glass disposed on the exposed surface of said element, said first type of glass having apredetermined working temperature; and a coating of a second type of glass disposed on top of said sintered layer, the working temperature of said second type of 7 glass being less than-said predetermined working temperature, whereby said first and second types ofglass provide a seal having physical characteristics substantially equiva lent to said predetermined physical characteristics of the ferrite element.
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Description
MarchIO, 1959 A. H. IVERSEN VITREOUS COATED MAGNETIC MATERIAL Filed May 19. 1954 United States Patent 2,877,144 7 VITREOUS COATED MAGNETIC MATERIAL Arthur H. Iversen, Santa Monica, Calif., assignor to Hughes Aircraft Company, Culver City, Calif., a corporation of Delaware Application May 19, 1954, Serial No. 430,841
4 Claims. (Cl. 117-215) This invention relates to hermetically-sealed ferromagnetic dielectric materials and a method for sealing the same, and more particularly to vitreous-coated ferromagnetic dielectric compacts and a method for applying a vitreous coat to such materials.
Ferromagnetic dielectric materials, known in the art simply as ferrites, are crystalline ceramics in which the major constituent is iron oxide. These ceramics are generally formed into a compact by a closel'yacontrolled sin-' tering process from a powder mixture which includes a plurality of bivalent-metal oxides. Ferrite compacts have a wide range of physical and electrical properties which are dependent on their composition and the sintering technique employed in their formation.
The ferromagnetic dielectrics are particularly useful in microwave applications because at these frequencies they exhibit a characteristic known as the Faraday effect. However, in use, the heating efiect, power factor, and
polarization rotating ability of the ferrite compacts are adversely affected by increasing moisture content.
An example of such utilizations of the ferrite compacts,
is shown in copendin'g application, Serial No. 419,259, by Willard A. Hughes, filed onMa'rch 29, 1954. In'this example the ferrite compact is utilized'to rotate incident wave energy 45 degrees for transmission to a load. The reflected energy is rotated another 45,degrees in again traversing the ferrite compact so that it has vafinal polarization at the source end of the ferrite; which is normal to that of the incident energy. This relationship between the'planes'of polarization of the incidentand reflected energyma kes it: feasible to divert thereflected energy out of th e workingsystem and soprevent it from traveling back to the source.
In addition to the utilization of the'ferrites in microwave-transmission systems, they arefalso useful in certain types of electron discharge devices such as, for example, the traveling wave type; The susceptibility of the ferrites to release occluded gases over a long period of time is an impediment to: this type of use because of the necessary high vacuum which'must be maintained in the electron discharge device. It follows that thisproblem can be obviated by hermetically sealingthe ferrite compact inaccorda'nce with the present invention. Accordingly, it follows that if the ferrite compacts can be hermetically sealed in an envelope or skinin a dry condition, their usefulness will .be very much enhanced. The manner in which thev ferrites are utilized, as well as their inherent physical properties, interposes a number of difiiculties in the way of achieving a's'atisfactory hermetic envelope.
lized in high intensity microwave applications which cause considerable heating of the compact. It follows that a sealing skin for the compact must be capableyof withstanding at temperature of at least severalhundred degress centigrade ,without deterioration, cracking or otherwiserdeveloping porosity.- The substances capable of The ferromagnetic dielectric compact or ferrite is im-f "ice performing a sealing function at these temperatures are the vitreous products, notably, glass.
An obstacle in the way of utilizing a vitreousv skin onferrite compacts is the inherent susceptibility of the compact to deterioration, i. e., cracking, due to thermal shock. That is, the tensile and compressive strengths of theferrite compact are insuflicient to prevent disrup-, tion of the compact due to sudden heating to a high temperature of the outer surfaces thereof. Consequently, since a glass surface must be applied to the compact at the molten temperature of the glass, it is necessary to utilize a glass which has a temperature of melting which is not so high as to cause breakup or cracking of the compact. On the other hand, because, as previously, mentioned, the ferrite compact can become quite hot in' operation, it is necessary to utilize a glass which has a high enough melting temperature to withstand deterioration of the glass skin or envelope.
In addition to the above problems involved'tin providing a ferrite compact with a vitreous coat or skin, itis also necessary that the compact with its vitreous skin withstand variations in temperature over several hundred degrees centigrade without deterioration of either the compact or seal. This requires that the vitreous substance uitlized for sealing the compact have a coefficient of thermal expansion sufliciently similar to that of the ferrite compact to limit the stresses in either the skin or the, compact itself so as to avoid deterioration of. either the skin or the compact.
"It. follows that a prime objective of this invention vis to provide a sealing coat or skin onto a ferromagnetic dielectric compact.
A further objective of this invention is to providev a method for applying a vitreous coating to ferromagnetic dielectric compacts.
The novel features which are believed to be characteristic of the invention, both as to its organization and method ofoperation, together with further objects and advantages thereof will become apparent from the fol lowing description considered in connection with the accompanying drawing, made a part of this specification.
In the drawing; Fig. 1" is a partial broken section of a hermetically sealed ferromagnetic ferrite device of the present inven tion; and a Fig. 2 is an enlarged cross-sectional view, section 22.' of the device shown .in Fig. 1. p 7
Referring to the figures of the drawing, a typical embodiment of the present invention is shown comprising an elongated ferrite compact or slug 10 having a. glass coating or skin 11 which hermetically seals the compact 10.,from the surrounding medium. shown, the diameter of the middle portion of thecompact is of the order of from 0.1 to 1.0 inch and its length is generally within the range of from one to four inches, the dimensions being determined by the particular application. Inasmuch as ferrites may be used in numerous other forms such as, for example, hollow or solid cylinder, it is readily apparent that the scope of the present: invention is not limited to the sizes mentioned or particu-- larfconfiguration shown. .7
In order to provide a suitable glass skin on the ferrite compacts, it is first necessary to determine the physical properties of the ferrite. Ferrites of many varied and diverse. compositions are commercially available. Many different compositions are employed because of the unusually large number of combinations of different useful physical properties exhibited by all of them. 'Representa tive' samples of a ferromagnetic ferrite may contain the following constituents: MnO, MnO CuCO ZnO, Z
Patented Mar. 10, 19,59
In the embodiment mally chemically reactive with lead peroxides and borates but they are not reactive with oxides of aluminum or magnesium or the carbonatesof sodium or calcium.
, The mineral magnetite, FeOFe O is the well-known, ferro-ferrite occurring in nature. Past experiments have led to success in making synthetic ferrites with both soft" and permanent magnetic properties. Due to the absence of metal components and in view of their dense structure, ferrites have relatively high volume resistivity and high permeability-in comparison to powdered iron materials. Their specific gravity lies between4 and 5 and their dielectric constant is about 9. These and other peculiar properties have led to a wide field of applications, many of which, as previously mentioned, require ferrites to be hermetically sealed.
The thermal coefficient of expansion of ferrites is primarily limited to the range 71 to 93 inch per inch per C. They have a relatively high modulus of elasticity and their ultimate strength is usually about 10,000 p. s. i., i. e., pounds per square inch, in compression and 2000 p. s. i. in tension. These three physical properties are generally the most important when correlated with those of glass, the thermal expansion coefficient normallybeing the most important of the three.
To produce a hermetic seal that will Withstand high vacuum and large temperature variations, glass probably has better physical and chemical properties than any other material. In obtaining a glass seal for a material it is necessary for the glass to wet and to match the material. Since most all glasses wet metal oxides, there is obviously no problem presented with respect to this requirement in coating ferrites since they. are almost totally constituted of the oxides of bivalent metals. What is normally meant by matching a glass to a material is to seek out a glass having a thermal coefiicient of expansion near enough to that of the material to prevent a structural failure in either by stresses set up by differential expansion. I v
In the manufacture of a good seal, being able to match a glass and a material from the standpoint of thermal expansion, i. e., being able to keep the strains in the glass or the material below their breaking strength in case their thermal expansions do not match, is not sufiicient' when accomplished only at room temperature because the glass and material must first of all be heated to a high temperature in order to make the seal. For this purpose, the glass is heated to its working temperature, the temperature above that at which it begins to soften or change its shape. In fact, the glass should be rendered plastic or fluid-like so that it will wet the material and stick thereto. Such a temperature is in the neighborhood of 800 C. or higher,
although, as it will be seen, one type of useful glass hasv a working temperature of 560 C.
The working temperature of a glass is to be distinguished from the softening temperature which may be as low as 440 C. and which is defined as being the temperature at which the glass becomes suificiently yielding "so that strains are relieved at an extremely rapid rate or within a. very short period, for example, less than one minute. The seal is then allowed to cool directly to room temperature or, as is the more usual case, the cooling process is temporarily arrested at a predetermined elevated temperature, termed the annealing" point or the lowest temperature below the softening temperature at which 90% of the internal stresses of the glass will be removed in about fifteen minutes.
In choosing a suitable glass in which to seal a ferrite,"
glass formed in such a batch requires, for melting, temperatures of about 1700 C. which temperatures are too expensive and impractical to achieve even with the best commercial glass-furnace refractories. Also, the resultant glass is so viscous, even at melting temperatures, that it can be homogenized and shaped only with great difiiculty. Consequently, for fiuxing or lowering the melting temperature, some sodium, or potassium oxide, or both,
usually 319% total, and some correlated amounts of one or more of the stabilizing and modifying oxides such as type glasses, namely, borosilicate glass; and 96% silica.
glass, and pure silica glass or quartz. This listing is more or less in order of increasing silica content, increasing mechanical durability, improving electrical properties, increasing cost, increasingshaping difficulty, and decreasing thermal expansion coefiicient.
The composition of these types, given in Table I, are
the analyses of the finished glasses for elements, except oxygen, converted to oxide equivalent.
Table I.-C0mp0siti0ns of commercial glasses Composition, percent Component Soda-lime Lead Borosili- 96% Silica eate Silica glass S10: 7075 (72) Na7O 12-18 (15) K20-.. 1 02.0 5-14 (9) PhD ros A1102" 0.5-2.5 (1;
The figures in parentheses give the approximate composition of a typical member.
In order to make a successful seal, the expansion of ferrite 10 and glass 11 must be substantially the same over the temperature range within which the glass is elastic. A large difference in expansion between them produces stresses which may cause either or both to crack when cooled to room temperature. Some degree of differential expansion, however, is tolerable and sometimes desirable.- The relaxation characteristics of the glass determine the upper temperature limit to which matched expansion is essential. Obviously, at temperatures where the glass is substantially plastic, equal expansion is no longer necessary.
The glasses which are most useful in practicing the present invention are then the soft glasses, the sodalime glasses and the lead glasses. The thermal coeflicients C. Although soft glasses may go lower to possibly 10"' inch per inch per C., few will go as high I as 140X10- inch per inch per C. Fused silica or silica glass has a coetficient of expansion which is too low for the present purposes, being about 5.5X10'- inch per inch per C. and 96% silica glass likewise has too low,a coefficient of expansion, being about 8 lO-' inch per inch per C. The glasses called borosilicate glasses contain 5% or more of boric oxide. They are also usually too hard to seal a ferrite, the range of their thermal expansion coefficients being about 13 to 60x10- inch per inch per C.
Glass in general has an ultimate strength in compression and tension ranging respectively from 90,000 to. 180,000 and from 4,000 to 1,000,000 p. s. i. The ultitriate strength in tensioni's normally r'fiuch' 'less than 1,000,000 p.;-s. i. except: for very small glassfibers. It. is however, pertinent to note tlzat the use ofany glass with a.ferrite demands that the thermal expansion coefficients be well. matched to prevent a structural failure particularlyyin'the ferrite because of thelow ultimate strength of the latter.
1 Nextin importance to the thermal expansion coelficient' is the modulus of elasticity of a glass. This :is. true be cause the glass should also be pliable at low temperatures to be. able to take a large deformation with very little stress; i. e., its modulus of elasticity should be as low as possible. Youngs modulus, does not appear to. bees: pecially related to the hardness of a glass or to any particular element of itscomposition. It is also true that there appears to'be -nocorrelati0n between Youngs modulus and thethermal expansion coeflicient. This moduljus of elasticity, however, does not normally vvaryappreciably for soft glasses of commoncompositions andis, therefore, not nearly so important as the thermal expansion of-;glass;.-- For example, all vYouug srrn'cpduli of glasses fall within the range 65. to 127x10 p .s. i. Some go as low as 76x10 p. 's. if-with a thermal expansioncoeflicient. of 79.6 inch per inch C. The moduli *ofzhard glasses are. scattered overv an equally wide range,.going as low as 68x10? p. s. i. for a glass having a thermal expansion, coefiicient of 32X 10" inch. per inch per.. C; and going as high'as 127 10" p. s. i.-f0r thermal expansion coefi'icient of 42x10- inch. per inch per C. I
pAlthough the soft glasses are generallysatisfactoryfor coating a ferrite, there are a few. glasses whichmay be used toaparticular advantage to reduce the riskz'of structural. failures during. the manufacture of. the seal. and especially: during the handlingof the component materials. For example, in the case of ferrites having a thermal expansion coeflicient falling within the range 71 86 10' inch per inch per C., it has been an effective expansivity between 65 and l00 l0 inch per inch per C. A glass having characteristics approximating these is commonly known as lime glass. This glass is composed of 73.3% SiO 15.6% Na O; 5.4% CaO; 3.8% MgO; 1.4% R 0 0.5% K 0 and has an effective expansivity of 92i2 10- inch per inch per C., and a Youngs modulus of 98 l0-' p. s. i.
It has also been found that a seal between the soft glasses known to the trade as 0080 and 7570 manufactured by the Coming Glass Company may be used in hermetically sealing the ferrites of the above description. The Corning Glass Company designates clear sealing bulb glass and solder glass with the number 0080 and 7570, respectively. These glasses are kept as closely as possible to a standard chemical composition at all times.
In order to apply the glass coating 11 to the ferrite slug 10, a suitable glass of the above-described types is first powdered and then suspended in a liquid such as, for example, water, methyl alcohol, or a solution of nitrocellulose in amyl acetate. This suspension of powdered glass is then brushed or sprayed uniformly over the ferrite slug 10 or alternatively, the ferrite slug 10 may be immersed in a suspension of powdered glass in the solution of nitrocellulose in amyl acetate.
The ferrite slug 10 covered with the suspension of powdered glass is then heated in a controlled atmosphere to the working temperature of the glass and then slowly cooled. This process is repeated until the glass coating 11 has a glaze finish and is of a suitable thickness. The thickness of glass coating 11 depending on the uses to which the ferrite is to be put is of the order of from 0.003 inch to more than 0.06 inch, the thinner coatings being used where permissible in that the electrical losses are less.
Referring again to Fig. 1, it is seen that glass coating 11 of the device has elongated pointed ends 12 where this, it is necessary for the electromagnetic wave to propagate through the medium of the device. In that the dielectric constant of ferrite is quite high, there is generally an impedance mismatch between the medium surrounding the device and the medium of the ferrite slug-10. Thus,
if the glass has a dielectric constant approximately equal to the geometric mean of the dielectric constants of :the surrounding and ferrite mediums, it may be employed to substantially improve theimpedance match of the ferrite slug 10 to the surrounding medium. The thicknessof glass points 12 for optimum matching as. measured along the longitudinal axis of. the device is of the orde.
of one-half guide wavelength.
-A glass suitable for making the glass points 12 isknoivn some ferrites that they .are sufiiciently porous so as to continuously absorb the glass when heated to the fluid state. This effect is to be avoided in that the characteristicsofthe ferrite aredeleteriously effected. According toathepresent invention, ferrites of this type are sealed. by first applying a coatingof glass having a-high work-.
ing temperature to the ferrite. This coating will generally not effectively seal the ferrite but it will prevent subsequent coatings of glass having a lower working temperature from being absorbed into the ferrite.
More particularly, this process of hermetically sealing a porous ferrite is as follows:
(1) Suspend powdered Corning glass 0080 in water.
(2) Brush glass 0080 onto the ferrite.
(3) Heat glass 0080 in an oven in air to its sintering temperature, i. e., the temperature at which substantial fusion but not fluidity is indicated, e. g., 700800 C.
(4) Allow the glass and the ferrite to cool.
(5) Brush a liquid suspension of powdered Corning glass 7570 over the sintered 0080 glass.
(6) Heat the ferrite and glasses to the working temperature of the 7570 glass, i. e., about 560 C.
(7) Allow both glasses and ferrite to cool.
Corning glass 7570 by itself has utility in the manufacture of the ferrite seal of the present invention in that its working temperature is 560 C. whereas most other glasses have a working temperature above 800 C. The use of this glass reduces the risk of structural failure due to the low thermal shock resistance of ferrites. Corning glasses 7570 and 0080 have thermal expansion coefficients of 84 and 92X 10- inch per inch per C., respectively, and in this regard are useful in preventing differential stresses. Youngs modulus of Corning 7570 is within the usual soft glass range. Likewise, Corning 0080 has a Youngs modulus of 98x10" p. s. i.
A few other glasses may also be used to hermetically seal a ferrite material. Among these glasses are clear sealing glass which is designated by the present Corning number code by 8870. Its application is somewhat limited particularly because of its high dielectric constant, viz., 9.5; however, its thermal expansion coefiicient is 91 X 10- inch per inch per C. and a large advantage accompanying its employment is its modulus of elasticity, 76 10-" p. s. i., which is comparatively low.
What is claimed is:
1. A device comprising an element composed of a porous ferromagnetic dielectric ceramic, said element having predetermined physical characteristics; a sintered layer of a first type of glass covering the exposed surface of said element, said first type of glass having a predetermined working temperature; and a coating of a second type of glass disposed on top of said sintered layer, the working temperature of said second type of glass being more than 80 C. lower than said predetermined working temperature, and said first and second types of glasses having thermal coefficients of expansion of from 65 to 120 X10 inch per inch per degree centigrade, whereby said first and second types of glass provide a seal having physical characteristics substantially equivalent to said predetermined physical characteristics of the ferrite element.
2. The method of hermetically sealing a normally porous ferromagnetic dielectric compact employing first and second types of glasses having first and second predetermined softening temperatures, respectively, said first softening temperature being higher than said second softening temperature, said method including the steps of producing first and second liquid suspensions of said first and second types of glasses, respectively; applying said first liquid suspension to the surface of said compact; heating said compact to the fusing temperature of said first type of glass to produce a coating of said first type of glass on said compact that partially seals the surface thereof; applying said second liquid suspension to the coated surface of said compact; and heating said compact to a temperature not less than the softening temperature of said second type of glass and less than the softening temperature of said first type'of glass.
3. A device comprising an element composed of a porous ferromagnetic dielectric ceramic, said element having predetermined physical characteristics; a sintered layer of a first type of glass disposed on the exposed surface of said element, said first type of glass having apredetermined working temperature; anda coating of a second type of glass disposed on top of said sintered layer, the working temperature of said second type of 7 glass being less than-said predetermined working temperature, whereby said first and second types ofglass provide a seal having physical characteristics substantially equiva lent to said predetermined physical characteristics of the ferrite element. r
4. The method of hermetically sealing a normally porous ferromagnetic dielectric compact employing first and second types of glasses having'first and second predetermined softening temperatures, respectively, said first softening temperature being higher than said second softening temperature, said method comprising the steps of producing a glaze of said first type of said glasses over the exposed surface of said compact, and producing a glaze of said second type of said glasses over the exposed surface of said first type of said glasses.
References Cited in the file of this patent UNITED STATES PATENTS 612,839 Gallinowsky Oct. 25, 1898 1,221,561 Meyer Apr. 3, 1917 1,663,660 Hottinger Mar. 27,1928 2,076,869 Tanner Apr. 13, 1937 2,568,881 Albers-Schoenberg Sept. 25, 1951 2,570,299 Zademach et al. Oct. 9, 1951 2,598,371 Gusdorf May 27, 1952 2,643,336 Valensi June 23, 1953 2,677,055 Allen Apr. 27, 1954 2,685,539 Woodburn et a1 Aug. 3, 1954 2,745,069 Hewitt May 8, 1956 2,748,353 Hogan May 29, 1956 UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 2,877,144 March 10, 1959 Arthur H. Iversen It is hereby certified that error appears in the printed specification of the above numbered patent requiring correction and that the said Letters Patent should read as corrected below.
Attest:
KARL Hn AXLINE Attesting Oflicer ROBERT cl WATSON Commissioner of Patents UNITED STATES I PATENT OFFICE CERTIFICATE OF CORRECTION Patent No. 2,877,l44 March 10, 1959 Arthur H. Iversen It is hereby certified that error appears in the printed specification of the above numbered patent requiring correction and that the said Letters Patent should read as corrected below.
Attest:
KARL H. AXLINE Attesting Oflicer ROBERT c. WATSON Commissioner of Patents
Claims (1)
1. A DEVICE COMPRISING AN ELEMENT COMPOSED OF A POROUS FERROMAGNETIC DIELECTRIC CERAMIC, SID ELEMENT HAVING PREDETERMINED PHYSICAL CHARACTERISTICS; A SINTERED LAYER OF A FIRST TYPE OF GALSS COVERING TRHE EXPOSED SURFACE OF SAID ELEMENT, SAID FIRST RYPE OF GLASS HAVING A PREDETERMINED WORKING TEMPERATURE; AND ACOATING OF A SECOND TYPE OF GLASS DISPOSED ON TOP OF SAID SINTERED LAYER, THE WORKING TEMPERATURE OF SAID SECOND TYPE OF GLASS BEING MORE THAN 80*C. LOWER THAN SAID PREDETERMINED WORKING TEMPERATURE, AND SAID FIRST AND SECOND TYPES OF GLASSES HAVING THERMAL COEFFICIENTS OF EXPANSION OF FROM 65 TO 120X10-7 INCH PER INCH PER DEGREE CENTIGRADE, WHEREBY SAID FIRST AND SECOND TYPES OF GLASS PROVIDE A SEAL HAVING PHYSICAL CHARACTERISTICS SUBSTANTIALLY EQUIVALENT TO SAID PREDETERMINED PHYSICAL CHARACTERISTICS OF THE FERRITE ELEMENT.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US430841A US2877144A (en) | 1954-05-19 | 1954-05-19 | Vitreous coated magnetic material |
US627930A US2894224A (en) | 1954-05-19 | 1956-12-12 | Ferromagnetic microwave device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US430841A US2877144A (en) | 1954-05-19 | 1954-05-19 | Vitreous coated magnetic material |
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US2877144A true US2877144A (en) | 1959-03-10 |
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US430841A Expired - Lifetime US2877144A (en) | 1954-05-19 | 1954-05-19 | Vitreous coated magnetic material |
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Cited By (10)
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US2908878A (en) * | 1955-05-27 | 1959-10-13 | Robert F Sullivan | Microwave switching device |
US3030257A (en) * | 1957-12-02 | 1962-04-17 | Rea Magnet Wire Company Inc | Heat resistant insulated electrical components and process of making |
US3085899A (en) * | 1960-05-23 | 1963-04-16 | Nat Resistance Corp | Means and method for forming electrical components |
US3105946A (en) * | 1954-11-19 | 1963-10-01 | Philips Corp | Asymmetrically conductive transmission system using adjacent dielectric plate to concentrate field in gyromagnetic plate |
US3110619A (en) * | 1961-05-15 | 1963-11-12 | Cons Electrodynamics Corp | Insulated electrical conductor |
US3484266A (en) * | 1966-07-05 | 1969-12-16 | Smith Corp A O | Method of internally coating tubular members with glass |
US3849190A (en) * | 1973-04-20 | 1974-11-19 | Ibm | Dielectric glass overlays and method for producing said glass compositions |
US3934061A (en) * | 1972-03-30 | 1976-01-20 | Corning Glass Works | Method of forming planar optical waveguides |
US4101707A (en) * | 1977-04-04 | 1978-07-18 | Rockwell International Corporation | Homogeneous multilayer dielectric mirror and method of making same |
DE19637147B4 (en) * | 1995-09-14 | 2007-04-19 | Nippon Electric Glass Co., Ltd., Otsu | Glass for a fluorescent lamp glass tube and its use |
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US3105946A (en) * | 1954-11-19 | 1963-10-01 | Philips Corp | Asymmetrically conductive transmission system using adjacent dielectric plate to concentrate field in gyromagnetic plate |
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US3484266A (en) * | 1966-07-05 | 1969-12-16 | Smith Corp A O | Method of internally coating tubular members with glass |
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