US2275952A - Method of coating insulating materials on metal objects - Google Patents
Method of coating insulating materials on metal objects Download PDFInfo
- Publication number
- US2275952A US2275952A US241878A US24187838A US2275952A US 2275952 A US2275952 A US 2275952A US 241878 A US241878 A US 241878A US 24187838 A US24187838 A US 24187838A US 2275952 A US2275952 A US 2275952A
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- United States
- Prior art keywords
- metal
- insulating material
- mosaic
- film
- insulating
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J29/00—Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
- H01J29/02—Electrodes; Screens; Mounting, supporting, spacing or insulating thereof
- H01J29/10—Screens on or from which an image or pattern is formed, picked up, converted or stored
- H01J29/36—Photoelectric screens; Charge-storage screens
- H01J29/39—Charge-storage screens
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J29/00—Details of cathode-ray tubes or of electron-beam tubes of the types covered by group H01J31/00
- H01J29/02—Electrodes; Screens; Mounting, supporting, spacing or insulating thereof
- H01J29/10—Screens on or from which an image or pattern is formed, picked up, converted or stored
- H01J29/36—Photoelectric screens; Charge-storage screens
- H01J29/39—Charge-storage screens
- H01J29/41—Charge-storage screens using secondary emission, e.g. for supericonoscope
- H01J29/413—Charge-storage screens using secondary emission, e.g. for supericonoscope for writing and reading of charge pattern on opposite sides of the target, e.g. for superorthicon
- H01J29/416—Charge-storage screens using secondary emission, e.g. for supericonoscope for writing and reading of charge pattern on opposite sides of the target, e.g. for superorthicon with a matrix of electrical conductors traversing the target
Definitions
- the present invention relates to a coating insulating materials on metal surfaces.
- the invention has been developed more especially in connection with the production of arrangements for transmitting television signals of the kind in which an element having a surface is provided on which an optical image may be projected, the surface being capable of acquiring an electrical charge varying from point to point in the surface in dependence on the light and shade of the optical image projected thereon, this surface being scanned by a cathode ray beam to produce signal currents which may be used for the electrical transmission of the picture to a distant location.
- the electrode surfaces adaptedto acquire the method of.
- locally varying electric charge in accordance with the light and shade of an optical image may be produced by forming or applying particles of a metal such as silver on a non-conducting plate usually formed of mica, the silver or like particles being coated with a photo electric layer, the electron emission from which under the action of light produces the required locally varying charge.
- the reverse side of the supporting plate of mica from that on which the silver or like particles are supported is usually coated. with or has applied to it thin film or foil of conducting metal which may serve as an electrode.
- the mica plate In preparing mosaic electrodes as described above it is essential that the mica plate shall be of uniform thickness and quality throughout, otherwise the structure of the mica plate will have an influence on the locally produced electric charges so that undesired effects will appear in the picture as reproduced at the distant location.
- One object of the present invention is to provide a supporting plate for a mosaic electrode for use ina television transmitter which will be uniform throughout.
- FIG. 1 shows diagrammatically asection of a mosaic plate prepared inaccordance with my invention
- Fig. 2 shows a modificationof the embodiment of my inventionshown in Fig. l in which a wire mesh mosaic is provided instead of a metal plate
- Fig. 3 shows on a larger scale a cross-section of one of the wires coated in accordance with my invention.
- lithium borate which is capable of becoming vitrified after being fused. This is evaporated down in vacuo on to the metal surface to be insulated, the metal having been previously oxidised very lightly.
- the borate may be evaporated, for example, from spirals of a suitable metal such as tungsten or platinum or from metal crucibles ofthe same metals. Preferably the evaporation is discontinued when a borate film of a thickness of the order of from' ⁇ l0- to 10- mm.
- the coated metal surface being removed from the vacuum chamber in which the evaporation has been performed and stoved for a few seconds in an inert atmosphere at a temperature some 10 C. above the fusing point of the borate, whereby a vitreous insulating coating is formed on the metal. If the step of baking the coating of insulator is carried out in an inert atmosphere it is found that the degree of oxidation of the base metal is substantially unaffected by the baking operation.
- the borate is enabled to wet the surface of the metal plate upon fusion remains as a uniformly disposed film.
- the extent to which the oxidation of the metal surface is carried determines the electrical and thus does not'draw up into globules but insulation resistance of the borate fllm after fusion.
- the picture point resistance of the vitreous film can be made as low as two or three megohms. This would provide a means of forming a semiinsulating layer on a metal plate to form a base for a mosaic electrode for use in a television transmitter whereon the mosaic structure could be maintained at a given potential.
- the most uniform film is formed when the borate just fuses. If the furnace in which the coated object is stoved is too hot the increased mobility of the film causes it to wrinkle. After evaporation the'borate film, though insulating, is loose, powdery and easily fractured.
- the film may be toughened by baking it in air to just below its fusion point, though in this case the insulating film is porous to evaporated metals whereas the vitreous film obtained by stoving the plate at a temperature just above the fusing point of the insulating material is not porous. It will be appreciated that in some circumstances it may be desirable to have the film of insulating material porous.
- lithium borate is preferred as the insulating material because of its low secondary emission when bombarded by electrons and also because it does not poison caesium-silver oxide surfaces, or rob such surfaces of too much caesium.
- the invention enables a mosaic to be provided for use in a television transmitter using a simple and clean process which results in a mosaic which itself allows the production of a picture with a clean back-ground.
- an insulator can be applied uniformly to very small metal ob- Jects such as very thin wires of copper and to intricate structures such as grids of fine metal wire which for instance, may be used in electron multipliers or like devices. It is also possible with the method of the invention to obtain thinner films of insulating material than by ordinary enamelling processes.
- photo electric surfaces especially of the mosaic type formed on an insulating surface arranged on a metal back plate in accordance with the invention may 'be readily constructed with a good useful sensitivity due to the fact that the insulation resistance of the insulating support can be so readily controlled, and hence the photo electric current may be saturated.
- a sheet of insulating material coated or applied on a conducting base according to the invention is extremely flexible.
- sheet metal coated by the method of the invention can be bent sharply to curves of radius less than a quarter of an inch and straightened again without fracturing the insulating coating.
- fiat sheets of material of such low strength that they can be deformed without crushing the insulating layer may be insulated .
- a metal member with an insulating surface in the case where the shape of the member is such that its surface would normally be difficult to insulate.
- wires may be coated in long lengths and be bent into shape as required.
- an insulating coating may be obtained which is perfectly stable and hard at high temperatures, for example up to at least 625 C. in vacuo, or up to about 800 C. in air.
- Such a surface can therefore be used in cases where, for example, considerations of space, required the use of small wire to pass a relatively large electric current, for'example in an internally arranged focussing coil in an electron discharge device such as a picture intensifier.
- wire of small gauge coated with an insulating layer by the method of the invention could be used and a large amount of heating could be tolerated without risk of damaging the insulation.
- the invention also might be, with advantage, applied to the construction of electrical inductances or resistances which are required to operate with a relatively high load current.
- the structure has the form shown in Fig. 1 in which the metal plate II has interposed between it and the insulating material IS an oxidized layer of metal 13.
- a wire mesh is used to prepare a double sided mosaic as shown in Figs. 2 and 3 in which the wire 3
- Such mosaics are well known in the art as is typified by that shown in U. S. Patent No. 2,045,984 to Flory.
- the method of producing an insulating layer on an oxidizable metal base the steps of oxidizing a surface of the. metal base, vaporizing a fusible inorganic insulating material having relatively low secondary emission under electronic bombardment, condensing the vaporized material upon the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
- a mosaic electrode having a metal base the steps of oxidizing a surface of the metal base, vaporizing a fusible inorganic insulating material having relatively low secondary emission under electronic bombardment, condensing a thin layer of the vaporized material upon the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
- a mosaic electrode having a metal base the steps of oxidizing a surface of the metal base, vaporizing a fusible inorganic insulating material having relatively low secondary the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
- a mosaic electrode having a metal base the steps of oxidizing a surface of the metal base, vaporizing lithium borate, condensing the vaporized lithium borate upon the oxidized surface to provide a thin layer thereon, fusing the layer of lithium borate in an inert atmosphere at a temperature substantially ten degrees centigrade above the fusing point of lithium borate and subsequently cooling the metal base to provide an extremely flexible coating of lithium borate upon the metal base.
- a mosaic electrode having a metal base the steps of oxidizing a surface of the metal base, vaporizing lithium borate, condensing the vaporized lithium borate upon the oxidized surface to provide a layer having a thickness lying between 10- and 10- mm. thereon, fusing the layer of lithium borate in an inert atmosphere at a temperature substantially 10 degrees centigrade above the fusing point of lithium borate and subsequently cooling the metal base to provide an extremely flexible coating of lithium borate upon the metal base.
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- Cathode-Ray Tubes And Fluorescent Screens For Display (AREA)
Description
March 10, 1942- G. s. P. FREEMAN METHOD OF COATING INSULATING MATERIALS ON METAL OBJECTS Filed Nov. 22, 1938 INVENTOR. 650/?65 STANLEY PERCIVAL FREEMAN A TTORNEY.
Patented Man-10, 1942 'r ME'rno'n or coa'rmo. msnm'rme MATERIALS on METAL onmc'rs George Stanley Percival Freeman, Hammersmith,
London, England, assignor to Electric & Muai-' cal Industries Limited, Hayes, Middlesex, England, a company of Great Britain Application November 22 In Great Britain Claims.
The present invention relates to a coating insulating materials on metal surfaces.
The invention has been developed more especially in connection with the production of arrangements for transmitting television signals of the kind in which an element having a surface is provided on which an optical image may be projected, the surface being capable of acquiring an electrical charge varying from point to point in the surface in dependence on the light and shade of the optical image projected thereon, this surface being scanned by a cathode ray beam to produce signal currents which may be used for the electrical transmission of the picture to a distant location.
The electrode surfaces adaptedto acquire the method of.
, 1938, Serial No. 241,878
November 22, 1937 provide a conducting-plate with an insulating surface layer of which the insulation resistance r can be controlled.
According to the invention a method of forming I rial.
locally varying electric charge in accordance with the light and shade of an optical image may be produced by forming or applying particles of a metal such as silver on a non-conducting plate usually formed of mica, the silver or like particles being coated with a photo electric layer, the electron emission from which under the action of light produces the required locally varying charge. The reverse side of the supporting plate of mica from that on which the silver or like particles are supported is usually coated. with or has applied to it thin film or foil of conducting metal which may serve as an electrode.' Electrodes thus prepared are termed mosaic electrodes, or mosaics."
In preparing mosaic electrodes as described above it is essential that the mica plate shall be of uniform thickness and quality throughout, otherwise the structure of the mica plate will have an influence on the locally produced electric charges so that undesired effects will appear in the picture as reproduced at the distant location.
Attempts have been made to form supporting plates for mosaic electrodes by evaporating an insulating material onto a supporting plate. However as far as my investigations go, I have found it difflcult to produce a uniform vitreous layer of insulating material on a metal supporting plate due to the fact that insulating material does not readily attach itself to the metal and tends to form globules on the plate when fused rather than to become evenly distributed over the plate.
One object of the present invention is to provide a supporting plate for a mosaic electrode for use ina television transmitter which will be uniform throughout.
A further object of the present invention is to In describing my invention in detail, reference will be-made to the drawing in which Fig. 1 shows diagrammatically asection of a mosaic plate prepared inaccordance with my invention, while Fig. 2 shows a modificationof the embodiment of my inventionshown in Fig. l in which a wire mesh mosaic is provided instead of a metal plate, and Fig. 3 shows on a larger scale a cross-section of one of the wires coated in accordance with my invention.
. In carrying the invention into practice in connection with mosaic electrodes for television transmission it is preferred to use as the insulating material, lithium borate, which is capable of becoming vitrified after being fused. This is evaporated down in vacuo on to the metal surface to be insulated, the metal having been previously oxidised very lightly. The borate may be evaporated, for example, from spirals of a suitable metal such as tungsten or platinum or from metal crucibles ofthe same metals. Preferably the evaporation is discontinued when a borate film of a thickness of the order of from'\ l0- to 10- mm. has been obtained, the coated metal surface being removed from the vacuum chamber in which the evaporation has been performed and stoved for a few seconds in an inert atmosphere at a temperature some 10 C. above the fusing point of the borate, whereby a vitreous insulating coating is formed on the metal. If the step of baking the coating of insulator is carried out in an inert atmosphere it is found that the degree of oxidation of the base metal is substantially unaffected by the baking operation.
Care must be taken to ensure that the borate film is not too thin initially, as in this case the finished surface will be covered with a large number of dry patches whence the borate has run away to thicken up the surrounding film. Moreover, if the borate film is too thick objectionable tendencies may appear in the-evaporated film in that the said film may tend to stand away from the metal and flake off, even in vacuo, or
even if the film does not actually begin to flake during evaporation it. may be wrinkled and uneven after fusion.
It is found that by oxidising the surface of th coated metal initially, the borate is enabled to wet the surface of the metal plate upon fusion remains as a uniformly disposed film. Moreover, the extent to which the oxidation of the metal surface is carried determines the electrical and thus does not'draw up into globules but insulation resistance of the borate fllm after fusion. For example, if a copper base is used, the picture point resistance of the vitreous film can be made as low as two or three megohms. This would provide a means of forming a semiinsulating layer on a metal plate to form a base for a mosaic electrode for use in a television transmitter whereon the mosaic structure could be maintained at a given potential.
In carrying the invention into practice it also has been found that. other conditions being favourable, the most uniform film is formed when the borate just fuses. If the furnace in which the coated object is stoved is too hot the increased mobility of the film causes it to wrinkle. After evaporation the'borate film, though insulating, is loose, powdery and easily fractured. The film may be toughened by baking it in air to just below its fusion point, though in this case the insulating film is porous to evaporated metals whereas the vitreous film obtained by stoving the plate at a temperature just above the fusing point of the insulating material is not porous. It will be appreciated that in some circumstances it may be desirable to have the film of insulating material porous. Where a coated metal plate prepared according to the invention is to be used in a television transmitter as described above, lithium borate is preferred as the insulating material because of its low secondary emission when bombarded by electrons and also because it does not poison caesium-silver oxide surfaces, or rob such surfaces of too much caesium.
The invention enables a mosaic to be provided for use in a television transmitter using a simple and clean process which results in a mosaic which itself allows the production of a picture with a clean back-ground. Moreover, with a process according to the invention an insulator can be applied uniformly to very small metal ob- Jects such as very thin wires of copper and to intricate structures such as grids of fine metal wire which for instance, may be used in electron multipliers or like devices. It is also possible with the method of the invention to obtain thinner films of insulating material than by ordinary enamelling processes. Moreover, photo electric surfaces (especially of the mosaic type) formed on an insulating surface arranged on a metal back plate in accordance with the invention may 'be readily constructed with a good useful sensitivity due to the fact that the insulation resistance of the insulating support can be so readily controlled, and hence the photo electric current may be saturated.
It is found that a sheet of insulating material coated or applied on a conducting base according to the invention is extremely flexible. Thus sheet metal coated by the method of the invention can be bent sharply to curves of radius less than a quarter of an inch and straightened again without fracturing the insulating coating.
Thus fiat sheets of material of such low strength that they can be deformed without crushing the insulating layer, may be insulated .ing a metal member with an insulating surface in the case where the shape of the member is such that its surface would normally be difficult to insulate. Also, according o the invention, wires may be coated in long lengths and be bent into shape as required.
Further, according to the invention, an insulating coating may be obtained which is perfectly stable and hard at high temperatures, for example up to at least 625 C. in vacuo, or up to about 800 C. in air. Such a surface can therefore be used in cases where, for example, considerations of space, required the use of small wire to pass a relatively large electric current, for'example in an internally arranged focussing coil in an electron discharge device such as a picture intensifier. In such a case wire of small gauge coated with an insulating layer by the method of the invention could be used and a large amount of heating could be tolerated without risk of damaging the insulation. The invention also might be, with advantage, applied to the construction of electrical inductances or resistances which are required to operate with a relatively high load current.
Where it is desired to provide a thin flexible plate for the mosaic, the structure has the form shown in Fig. 1 in which the metal plate II has interposed between it and the insulating material IS an oxidized layer of metal 13. In some instances a wire mesh is used to prepare a double sided mosaic as shown in Figs. 2 and 3 in which the wire 3| is oxidized to provide the layer of oxidized material 33 upon which is then deposited, as described above, the insulating material 35. Such mosaics are well known in the art as is typified by that shown in U. S. Patent No. 2,045,984 to Flory.
I claim:
l. The method of producing an insulating layer on an oxidizable metal base, the steps of oxidizing a surface of the. metal base, vaporizing a fusible inorganic insulating material having relatively low secondary emission under electronic bombardment, condensing the vaporized material upon the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
2. In preparing a mosaic electrode having a metal base, the steps of oxidizing a surface of the metal base, vaporizing a fusible inorganic insulating material having relatively low secondary emission under electronic bombardment, condensing a thin layer of the vaporized material upon the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
3. In preparing a mosaic electrode having a metal base, the steps of oxidizing a surface of the metal base, vaporizing a fusible inorganic insulating material having relatively low secondary the oxidized surface, fusing the condensed material in an inert atmosphere at a temperature immediately above the fusing temperature of the insulating material, and subsequently cooling the metal base to provide an extremely flexible coating of insulating material upon the metal base.
4. In preparing a mosaic electrode having a metal base, the steps of oxidizing a surface of the metal base, vaporizing lithium borate, condensing the vaporized lithium borate upon the oxidized surface to provide a thin layer thereon, fusing the layer of lithium borate in an inert atmosphere at a temperature substantially ten degrees centigrade above the fusing point of lithium borate and subsequently cooling the metal base to provide an extremely flexible coating of lithium borate upon the metal base.
5. In preparing a mosaic electrode having a metal base, the steps of oxidizing a surface of the metal base, vaporizing lithium borate, condensing the vaporized lithium borate upon the oxidized surface to provide a layer having a thickness lying between 10- and 10- mm. thereon, fusing the layer of lithium borate in an inert atmosphere at a temperature substantially 10 degrees centigrade above the fusing point of lithium borate and subsequently cooling the metal base to provide an extremely flexible coating of lithium borate upon the metal base.
GEORGE STANLEY PERCIVAL FREEMAN.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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GB2275952X | 1937-11-22 |
Publications (1)
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US2275952A true US2275952A (en) | 1942-03-10 |
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US241878A Expired - Lifetime US2275952A (en) | 1937-11-22 | 1938-11-22 | Method of coating insulating materials on metal objects |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2572497A (en) * | 1948-11-30 | 1951-10-23 | Rca Corp | Making fine mesh silica screens |
US2671746A (en) * | 1950-06-17 | 1954-03-09 | Richard D Brew & Company Inc | Bonding system |
US2754238A (en) * | 1951-05-22 | 1956-07-10 | David L Arenberg | Method of bonding and article thereby formed |
US2949390A (en) * | 1957-08-07 | 1960-08-16 | Harold M Feder | Method of protecting tantalum crucibles against reaction with molten uranium |
-
1938
- 1938-11-22 US US241878A patent/US2275952A/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2572497A (en) * | 1948-11-30 | 1951-10-23 | Rca Corp | Making fine mesh silica screens |
US2671746A (en) * | 1950-06-17 | 1954-03-09 | Richard D Brew & Company Inc | Bonding system |
US2754238A (en) * | 1951-05-22 | 1956-07-10 | David L Arenberg | Method of bonding and article thereby formed |
US2949390A (en) * | 1957-08-07 | 1960-08-16 | Harold M Feder | Method of protecting tantalum crucibles against reaction with molten uranium |
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