US1980675A - Method and means for preventing heater-cathode leakage in a radio tube - Google Patents
Method and means for preventing heater-cathode leakage in a radio tube Download PDFInfo
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- US1980675A US1980675A US608835A US60883532A US1980675A US 1980675 A US1980675 A US 1980675A US 608835 A US608835 A US 608835A US 60883532 A US60883532 A US 60883532A US 1980675 A US1980675 A US 1980675A
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- heater
- cathode
- leakage
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- coil
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
- H01J1/00—Details of electrodes, of magnetic control means, of screens, or of the mounting or spacing thereof, common to two or more basic types of discharge tubes or lamps
- H01J1/02—Main electrodes
- H01J1/13—Solid thermionic cathodes
- H01J1/20—Cathodes heated indirectly by an electric current; Cathodes heated by electron or ion bombardment
- H01J1/22—Heaters
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- C—CHEMISTRY; METALLURGY
- C04—CEMENTS; CONCRETE; ARTIFICIAL STONE; CERAMICS; REFRACTORIES
- C04B—LIME, MAGNESIA; SLAG; CEMENTS; COMPOSITIONS THEREOF, e.g. MORTARS, CONCRETE OR LIKE BUILDING MATERIALS; ARTIFICIAL STONE; CERAMICS; REFRACTORIES; TREATMENT OF NATURAL STONE
- C04B35/00—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products
- C04B35/01—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products based on oxide ceramics
- C04B35/08—Shaped ceramic products characterised by their composition; Ceramics compositions; Processing powders of inorganic compounds preparatory to the manufacturing of ceramic products based on oxide ceramics based on beryllium oxide
Definitions
- the cathode sleeve In vacuum tubes a common source of electron emission is a coated cathode element. There are two forms of cathodes, one which is heated directly and the other heated indirectly. Fre- 5 quently the indirectly heated cathode is an assembly or unit comprised of a core rod, a heater element, and a tubular sleeve, usually designated as the cathode sleeve. In order to produce electrons copiously, the cathode sleeve is coated with an electron emission material such as the oxides of the alkaline earth metals barium,y strontium and calcium, either singularly, or mixed in various proportions.
- an electron emission material such as the oxides of the alkaline earth metals barium,y strontium and calcium, either singularly, or mixed in various proportions.
- the heater element which is composed of a metal filament adapted to be connected to a source of electrical energy.
- the heater although generally spaced close to the cathode sleeve, must be electrically separate therefrom. This requires that the heater be completely insulated from the cathode sleeve, unless the sleeve is of sufficient diameter that the heater may be supported without danger of coming into contact with it. As the latter form of construction is not efficient because of losses inherent in wide spacing of the heater and cathode sleeve, itis almost the universal practice to have the heater closely spaced to the cathode sleeve.
- heater-cathode leakage may be defined as objectionable conduction between the heater coil and the cathode sleeve through the hot insulating coating material therebetween. In certain receiving set circuits leakage in excess of twenty-five microamperes is objectionable.
- Another object is the provision of a coating material for the heater coil having good insulating properties at high temperatures.
- Another object of the invention is the providing of a refractory composition which may be used for both the core rod and the insulating coating for the heater coil, without fear of any change in the physical properties of the composition being effected by diffusion thereof between these elements at high temperatures.
- Fig. 1 is an elevation, partly in section, of a heater assembly for a cathode of the indirectly heated type
- Fig. 2 is a perspective of the several parts cornprising the heater assembly.
- Fig. 3 is a greatly exaggerated view, partly in section, of the heater without the cathode sleeve.
- the construction of the heater assembly comprises a coil 1 of tungsten or the like, wound in the form of a double helix, with the ends thereof terminating in straight portions which serve as terminals for connecting the coil to a source of electrical energy.
- a core rcd 2 Inside of the coil 1 is inserted a core rcd 2 of proper length and diameter so as to be frictionally retained in position and extend throughout the coiled portion of the heater element.
- the function of the core rod is to lend support to the coil, but primarily is to prevent the short circuiting of the turns thereof.
- the filament for the heater When the filament for the heater is of larger diy ameter than five or six thousandths Iof an inch, it is well to insert over the endsof the filament a double hole plug 3 of refractory material in order to lock the ends of the filament.
- the assembled heater is inserted into a cathode sleeve 5, made of nickel and partly coated externally with an oxide of an electron emission material such as lnentioned above.
- this type of heater must not only be insulated from the cathode sleeve, but must also have the turns of the heater wire insulated from each other.
- the refractory insulation used in the construction thereof should, at temperatures of 1600-2000 C. be highly refractory and somewhat porous, have a low coeflicient of expansion, suflicient vitriiication to produce the desired mechanical strength, and above all a minimum of electrical leakage.
- the compositions of the various insulating parts are identical.
- the insulating parts should preferably be manufactured from the same refractory composition. I have found that if this is not the case, a transfer or diffusion of the more volatile constituents will take place at the high temperatures prevailing during the manufacture of the tube, thus altering the compositions of the various insulating parts and consequently their electrical leakage.
- Pure beryllium oxide is a light fluffy material which has a melting point around 2500 C., and which cannot be sintered or fritted together when heated at temperatures around 1600 C. for a substantial period; the material remaining practically unaltered in its physical properties after such treatment.
- beryllium oxide, containing or mixed with definite amounts of other materials of lower melting points, such as silica, magnesium silicate, etc. may be readily sintered or fritted when subjected to temperatures around 1600 C.
- the amounts of these additive materials necessary to produce a given shrinkage and increase in density varies considerably with the material used. For example, with .1% of silica very little change will be noted.
- a Satisfactory refractory material As one of the demands of a Satisfactory refractory material is that it shall havelsuflicient vitrification to produce the desired Strength at the temperature used, it is necessary to add a binder to the basic refractory material used.
- a binder For this purpose I prefer to use silica as it has been found that this material will give the necessary bonding action and at the same time will have no tendency to affect adversely characteristics of the finished tube, such as the electron emission.
- the sintered material 100 when removed from the boat is in the form of a brick, which is then placed in a porcelain ballmill with suiiicient denatured alcohol for efficient grinding and allowed to mill for fifteen hours, after which it is poured into glass trays and thoroughly dried ⁇ in. a low temperature oven. The ground material is then screened through a 200 mesh screen and bottled for use.
- the ground material is mixed with a suflicient 110 quantity of a paste carrier (made of a solution of nitrocellulose) to produce a dough, which is then extruded into-rods or plugs by means of a press through a suitable die.
- the rods or plugs are then baked in air at a temperature of 1600 C. 115
- a heater assembly for an indirectly heated cathode of an 'electron discharge tube comprising a tungsten wire wound into a helix around a vitried insulating core rod which consists of 95% beryllium oxide and 5% silica, and a thin vitriied insulating coating adherent to and covering both said wire and said core consisting of 95% beryllium oxide and 5% silica.
- a heater assembly for an indirectly heated cathode of an electron' discharge tube comprising a coil of tungsten wire supported on a vitriied insulating core rod consisting predominately of substantially pure beryllium oxide and approximately 5% of silicon dioxide, and a thin vitriiied insulating coating covering both said 150 wire and core and of the same composition as the core rod.
- a cathodedieater assembly for an electron discharge tube comprising a tubular cathode sleeve surrounding an electrically insulated heater assembly, said heater assembly consisting ⁇ of a noninductive helical coil of tungsten Wire 5.
- the method of preparing electrically insulating material for the heater element of an electron discharge tube which comprises mixing approximately 95% by weight of chemically pure uffy beryllium oxide with approximately 5% by weight of finely powdered dry silicon dioxide, heating said mixture in a hydrogen atmosphere at about 1600" C.
Description
NOV. 13,1934. M N, FREDENBURGH 1,980,675
A RADIO TUBE METHOD AND MEANS FOR PREVENTING HEATER CATHODE LEAKAGE IN Filed May 2, 1952 ATTORNEY- Patented Nov. 13, 1934 UNITED STATES PATENT OFFICE METHOD AND MEANS FOR PREVENTING HEATER-CATHODE LEAKAGE IN A RADIO TUBE Delaware Application May 2, 1932, Serial No. 608,835
Claims.
In vacuum tubes a common source of electron emission is a coated cathode element. There are two forms of cathodes, one which is heated directly and the other heated indirectly. Fre- 5 quently the indirectly heated cathode is an assembly or unit comprised of a core rod, a heater element, and a tubular sleeve, usually designated as the cathode sleeve. In order to produce electrons copiously, the cathode sleeve is coated with an electron emission material such as the oxides of the alkaline earth metals barium,y strontium and calcium, either singularly, or mixed in various proportions. As these oxides (in order to emit electrons freely) must be heated to a temperature of approximately 850 C., considerable heat must be applied to the cathode sleeve in order to maintain the ,necessary temperature. This heat is generated by the heater element which is composed of a metal filament adapted to be connected to a source of electrical energy.
The heater, although generally spaced close to the cathode sleeve, must be electrically separate therefrom. This requires that the heater be completely insulated from the cathode sleeve, unless the sleeve is of sufficient diameter that the heater may be supported without danger of coming into contact with it. As the latter form of construction is not efficient because of losses inherent in wide spacing of the heater and cathode sleeve, itis almost the universal practice to have the heater closely spaced to the cathode sleeve.
It is customary to use a filament coiled in the form of a double helix for the heater element, and in order to prevent short circuiting of the turns thereof, a ceramic core or plug is employed. The close spacing between the cathode sleeve and the heater requires that the heater wire itself be coated with a material having good electrical insulating properties at the operating temperature, say 900 to 1800" C. depending on the tube in order to avoid heater-cathode leakage. For the purpose of this specification heater-cathode leakage may be defined as objectionable conduction between the heater coil and the cathode sleeve through the hot insulating coating material therebetween. In certain receiving set circuits leakage in excess of twenty-five microamperes is objectionable. Moreover, variation in this leakage produces noise. f The refractory materials used in the past for the construction of the heaters have been quite satisfactory when used in connection with the average circuit, but with the higher potential differences between heater and cathode existing in the modern circuits, these materials have been (Cl. Z50-27 .5)
unsatisfactory with respect to their electrical leakage' and accompanying noise. As an example, it may be mentioned that electrical leakage, existing between heater and cathode is directly responsible foil producing disturbing noises in the loud speaker of a set using radio tubes having relatively high potential differences (as for instance, a bias of 50 to 100 volts) between heater and cathode, especially when such a tube is subjected to Vibration, either mechanical or acoustic.
It is, therefore, an object of the invention to prevent heater-cathode leakage, more particularly in radio tubes having high potential differences between the heater and the cathode.
Another object is the provision of a coating material for the heater coil having good insulating properties at high temperatures.
Another object of the invention is the providing of a refractory composition which may be used for both the core rod and the insulating coating for the heater coil, without fear of any change in the physical properties of the composition being effected by diffusion thereof between these elements at high temperatures.
Further objects of the inventiomwill manifest themselves as the description proceeds.
Referring to the accompanying drawing:
Fig. 1 is an elevation, partly in section, of a heater assembly for a cathode of the indirectly heated type;
Fig. 2 is a perspective of the several parts cornprising the heater assembly; and
Fig. 3 is a greatly exaggerated view, partly in section, of the heater without the cathode sleeve.
As shown in the drawing, particularly Fig. 2 thereof, the construction of the heater assembly comprises a coil 1 of tungsten or the like, wound in the form of a double helix, with the ends thereof terminating in straight portions which serve as terminals for connecting the coil to a source of electrical energy. Inside of the coil 1 is inserted a core rcd 2 of proper length and diameter so as to be frictionally retained in position and extend throughout the coiled portion of the heater element. The function of the core rod is to lend support to the coil, but primarily is to prevent the short circuiting of the turns thereof. When the filament for the heater is of larger diy ameter than five or six thousandths Iof an inch, it is well to insert over the endsof the filament a double hole plug 3 of refractory material in order to lock the ends of the filament. The assembled heater is inserted into a cathode sleeve 5, made of nickel and partly coated externally with an oxide of an electron emission material such as lnentioned above.
It will be noted that this type of heater must not only be insulated from the cathode sleeve, but must also have the turns of the heater wire insulated from each other. For satisfactory performance as heaters, the refractory insulation used in the construction thereof should, at temperatures of 1600-2000 C. be highly refractory and somewhat porous, have a low coeflicient of expansion, suflicient vitriiication to produce the desired mechanical strength, and above all a minimum of electrical leakage.
In the past it has been customary to manufacture the core rods and plugs by the extrusion, and final baking in air or hydrogen at 1600 C. Of an extrusion mixture made up of magnesium or aluminum oxide, together with a suitable fritting material such as silica and a paste carrier such as a solution of nitrocellulose. Thevspray mixture 4 used for coating the coil and core rod has been made heretofore of aluminum oxide, together with a suitable binding material such as silica and suspended kin a solution of nitrocellulose. After spraying the complete assembly is baked in hydrogen at a, temperature of 1600 C.
In an effort to prepare refractory compositions superior to those used in the past, I have discovered that pure beryllium oxide, when used as the basic constituent of the refractory mixture for the manufacture of the insulating parts of the heater, will prevent, or materially decrease, the electrical leakage, and thus prevent or materially decrease the noises due to such leakage. Also, the value of the oxide as an insulator materially increases as the percentage of other constituents decrease. l y
I have also discovered that the quality of the material as an insulator considerably increases when heated at a temperature of 1600 to 2000a C., for a substantial period, either in air, hydrogen, or Vacuum, but preferably in vacuum.
I have further discovered that in order to maintain the definite composition of the refractory materials comprising the various insulating parts.
of the heater, it is desirable to have the compositions of the various insulating parts identical. In other words, the insulating parts should preferably be manufactured from the same refractory composition. I have found that if this is not the case, a transfer or diffusion of the more volatile constituents will take place at the high temperatures prevailing during the manufacture of the tube, thus altering the compositions of the various insulating parts and consequently their electrical leakage. y
In order to reduce to actual practice the discoveries mentioned above, specific directions are given for the preparation of a refractory composition for the core rods, plugs, and spray coating, to be used in the manufacture of heaters having low electrical leakage while operating as part of a cathode.
Pure beryllium oxide is a light fluffy material which has a melting point around 2500 C., and which cannot be sintered or fritted together when heated at temperatures around 1600 C. for a substantial period; the material remaining practically unaltered in its physical properties after such treatment. On the other hand, beryllium oxide, containing or mixed with definite amounts of other materials of lower melting points, such as silica, magnesium silicate, etc. may be readily sintered or fritted when subjected to temperatures around 1600 C. The amounts of these additive materials necessary to produce a given shrinkage and increase in density varies considerably with the material used. For example, with .1% of silica very little change will be noted. As one of the demands of a Satisfactory refractory material is that it shall havelsuflicient vitrification to produce the desired Strength at the temperature used, it is necessary to add a binder to the basic refractory material used. For this purpose I prefer to use silica as it has been found that this material will give the necessary bonding action and at the same time will have no tendency to affect adversely characteristics of the finished tube, such as the electron emission.
In preparing the refractory composition 95% by weight of powdered pure beryllium oxide (alkali-free) is mixed with 5% by weight of pure fused silica, in `powder form, and thoroughly mixed together in a dry condition. AThe powdered material is then packed into a molybdenum boat and heated in a hydrogen furnace for onehalf hour at 1600 C. This treatment results in the material sintering and shrinking to about one-fourth its previous volume and increasing in density to about 400%. The sintered material 100 when removed from the boat is in the form of a brick, which is then placed in a porcelain ballmill with suiiicient denatured alcohol for efficient grinding and allowed to mill for fifteen hours, after which it is poured into glass trays and thoroughly dried `in. a low temperature oven. The ground material is then screened through a 200 mesh screen and bottled for use.
In the manufacture of core rods and end plugs the ground material is mixed with a suflicient 110 quantity of a paste carrier (made of a solution of nitrocellulose) to produce a dough, which is then extruded into-rods or plugs by means of a press through a suitable die. The rods or plugs are then baked in air at a temperature of 1600 C. 115
In the manufacture of the spray coating 100 gms. of the ground material are mixed with 200 ml. of a solution of nitrocellulose in a porcelain ball mill, and the material mixed for two hours, after which it is applied by means of a spray gun to the rotating heater assembly. The assembly is then dried at 100 C., after which it is placed in a molybdenum boat and baked in a hydrogen or vacuum furnace for five minutes at a temperature of 1500 C.
It is obvious from the foregoing that various modifications of my process will suggest themselves to those skilled in the art. As for example, the oxide used and the manner in which the refractory composition is prepared may be varied, as well as the percentage and/or composition of additive materials varied, but I intend to cover all such modifications as come Within the scope of the appended claims.
What is claimed is:
1. A heater assembly for an indirectly heated cathode of an 'electron discharge tube comprising a tungsten wire wound into a helix around a vitried insulating core rod which consists of 95% beryllium oxide and 5% silica, and a thin vitriied insulating coating adherent to and covering both said wire and said core consisting of 95% beryllium oxide and 5% silica.
2. A heater assembly for an indirectly heated cathode of an electron' discharge tube comprising a coil of tungsten wire supported on a vitriied insulating core rod consisting predominately of substantially pure beryllium oxide and approximately 5% of silicon dioxide, and a thin vitriiied insulating coating covering both said 150 wire and core and of the same composition as the core rod.
3. A cathodedieater assembly for an electron discharge tube comprising a tubular cathode sleeve surrounding an electrically insulated heater assembly, said heater assembly consisting `of a noninductive helical coil of tungsten Wire 5. The method of preparing electrically insulating material for the heater element of an electron discharge tube which comprises mixing approximately 95% by weight of chemically pure uffy beryllium oxide with approximately 5% by weight of finely powdered dry silicon dioxide, heating said mixture in a hydrogen atmosphere at about 1600" C. until it sinters into a compact coherent mass having a density about four-fold that of the fluffy beryllium oxide, grinding said sintered mass in denatured alcohol to a ne powder, drying said powder at approximately 100 C., screening said dried powder, and mixing said screened powder with a viscous liquid binder to make a suspension suitable for spraying or extrusion.
MARK N. FREDENBURGH.
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US608835A US1980675A (en) | 1932-05-02 | 1932-05-02 | Method and means for preventing heater-cathode leakage in a radio tube |
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US608835A US1980675A (en) | 1932-05-02 | 1932-05-02 | Method and means for preventing heater-cathode leakage in a radio tube |
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US608835A Expired - Lifetime US1980675A (en) | 1932-05-02 | 1932-05-02 | Method and means for preventing heater-cathode leakage in a radio tube |
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2677782A (en) * | 1950-10-27 | 1954-05-04 | Sylvania Electric Prod | Vacuum tube heater |
US3073986A (en) * | 1960-04-20 | 1963-01-15 | Gen Electric | Electric incandescent lamp |
US5118983A (en) * | 1989-03-24 | 1992-06-02 | Mitsubishi Denki Kabushiki Kaisha | Thermionic electron source |
US20210102698A1 (en) * | 2019-10-08 | 2021-04-08 | MHI Health Devices, LLC. | Superheated steam and efficient thermal plasma combined generation for high temperature reactions apparatus and method |
-
1932
- 1932-05-02 US US608835A patent/US1980675A/en not_active Expired - Lifetime
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US2677782A (en) * | 1950-10-27 | 1954-05-04 | Sylvania Electric Prod | Vacuum tube heater |
US3073986A (en) * | 1960-04-20 | 1963-01-15 | Gen Electric | Electric incandescent lamp |
US5118983A (en) * | 1989-03-24 | 1992-06-02 | Mitsubishi Denki Kabushiki Kaisha | Thermionic electron source |
US20210102698A1 (en) * | 2019-10-08 | 2021-04-08 | MHI Health Devices, LLC. | Superheated steam and efficient thermal plasma combined generation for high temperature reactions apparatus and method |
US11940146B2 (en) * | 2019-10-08 | 2024-03-26 | Mhi Health Devices, Inc. | Superheated steam and efficient thermal plasma combined generation for high temperature reactions apparatus and method |
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