IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0858781
(2010-08-18)
|
등록번호 |
US-8356492
(2013-01-22)
|
우선권정보 |
JP-2009-189379 (2009-08-18) |
발명자
/ 주소 |
- Suzuki, Kazuhiro
- Hayashi, Tomonari
- Asanuma, Shigeru
- Osakabe, Kinobu
|
출원인 / 주소 |
|
인용정보 |
피인용 횟수 :
0 인용 특허 :
5 |
초록
▼
Glass is mass-produced with a glass melting furnace comprising a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material, at least one pair of electrodes placed so as to be in contact with the molten glass held in the melting tank for ohmically he
Glass is mass-produced with a glass melting furnace comprising a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material, at least one pair of electrodes placed so as to be in contact with the molten glass held in the melting tank for ohmically heating the molten glass held in the melting tank; and at least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with the molten glass held in the melting tank. Every metallic member is, when the melting tank is filled with the molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by the electrodes into the molten glass held in the melting tank.
대표청구항
▼
1. A glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising:a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material;at least one pair of electrodes placed so as to be in contact wi
1. A glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising:a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material;at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; andat least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank;wherein:every one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andthe electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 2. The glass manufacturing method according to claim 1, wherein: each of said at least one metallic member is placed in a mode selected from the group consisting of: a mode in which it is movably placed so as to be substantially always outside said electric current flowing region; and a mode in which it is fixedly placed so as to be substantially always outside said electric current flowing region. 3. The glass manufacturing method according to claim 1, wherein said mass-producing of glass is carried by alternately repeating a melting step of charging glass material in said melting tank and melting the glass material and a discharge step of discharging from said melting tank the molten glass prepared by melting the glass material through said melting step. 4. The glass manufacturing method according claim 1, wherein: said melting tank is connected to a glass supply source that is one of a molten glass flow inlet through which the molten glass substantially continuously flows in said melting tank and a glass material charge inlet through which glass material is charged substantially continuously, and to a molten glass discharge outlet through which the molten glass is continuously discharged; and wherein:said mass producing of glass is carried by substantially continuously discharging, according to one of an inflow of the molten glass which flows through said molten glass flow inlet into said melting tank substantially continuously and an input of the glass material charged through said glass material charge inlet into said melting tank substantially continuously, the molten glass from said melting tank which is always filled with the molten glass. 5. The glass manufacturing method according to claim 1, wherein: said metal is at least one metal selected from the group consisting of platinum, platinum alloy, and strengthened platinum. 6. The glass manufacturing method according to claim 1, wherein: said at least one metallic member comprises at least one instrument selected from the group consisting of (1) a protective member of a temperature detector, the temperature detector including a temperature sensor and the protective member which covers said temperature sensor and at least a surface of which is made of metal, (2) an agitator which is used for agitating said molten glass and at least a surface of which is made of metal, (3) a pipe which is used for making said molten glass flow therethrough and at least a surface of which is made of metal, and (4) a gas ejector which is used for bubbling the molten glass and at least a surface of which is made of metal. 7. A glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising:a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material;at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; andat least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank, wherein:said wall surface is eroded as cumulative contact time between said molten glass and said wall surface increases to form two kinds of erosion surfaces, one of which is a low erosion region being away from said at least one pair of electrodes and having a relatively small amount of erosion of said wall surface and another of which is a high erosion region being in a vicinity of said at least one pair of electrodes and having a relatively large amount of erosion of said wall surface, and wherein:every one of said at least one metallic member is fixedly placed in advance before a start of mass producing of glass so as to be substantially flush with a wall surface which may be in said low erosion region at an end of said mass producing of glass; andevery one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andthe electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 8. The glass manufacturing method according to claim 7, wherein: said mass-producing of glass is carried by alternately repeating a melting step of charging glass material in said melting tank and melting the glass material and a discharge step of discharging from said melting tank the molten glass prepared by melting the glass material through said melting step. 9. The glass manufacturing method according to claim 7, wherein: said melting tank is connected to a glass supply source that is one of a molten glass flow inlet through which the molten glass substantially continuously flows in said melting tank and a glass material charge inlet through which glass material is charged substantially continuously, and to a molten glass discharge outlet through which the molten glass is continuously discharged; and wherein: said mass producing of glass is carried by substantially continuously discharging, according to one of an inflow of the molten glass which flows through said molten glass flow inlet into said melting tank substantially continuously and an input of the glass material charged through said glass material charge inlet into said melting tank substantially continuously, the molten glass from said melting tank which is always filled with the molten glass. 10. The glass manufacturing method according to claim 7, wherein: said metal is at least one metal selected from the group consisting of platinum, platinum alloy, and strengthened platinum. 11. The glass manufacturing method according to claim 7, wherein: said at least one metallic member comprises at least one instrument selected from the group consisting of (1) a protective member of a temperature detector, the temperature detector including a temperature sensor and the protective member which covers said temperature sensor and at least a surface of which is made of metal, (2) an agitator which is used for agitating said molten glass and at least a surface of which is made of metal, (3) a pipe which is used for making said molten glass flow therethrough and at least a surface of which is made of metal, and (4) a gas ejector which is used for bubbling the molten glass and at least a surface of which is made of metal. 12. A glass manufacturing method for mass-producing glass with a glass melting furnace by; filling a melting tank of said glass melting furnace with molten glass;ohmically heating said molten glass held in said melting tank by means of at least one pair of electrodes placed so as to be in contact with said molten glass; andplacing at least one metallic member, of which at least a surface is made of metal, to contact with said molten glass; whereinevery one of said at least one metallic member is placed outside an effective electric current flowing region formed by said at least one pair of electrodes into said molten glass; andthe electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 13. The glass manufacturing method according to claim 12, wherein said effective electric current flowing region comprises an opposing region in which each pair of said electrodes are immediately opposed to each other plus a peripheral region up to 60° upward and up to 30° sideways and downward from ends of said electrodes from said opposing region. 14. The glass manufacturing method according to claim 12, wherein each of said at least one metallic member is placed movably or fixedly outside said effective electric current flowing region at least in said ohmically heating. 15. The glass manufacturing method according to claim 12, wherein said mass-producing of glass is carried by alternately repeating:a melting step of charging glass material in said melting tank and melting said glass material through said filing and said ohmically heating; anda discharge step of discharging from said melting tank the molten glass prepared by melting the glass material through said melting step. 16. The glass manufacturing method according to claim 12, wherein said mass-producing of glass is carried by:supplying molten glass or glass material continuously to said melting tank to carry said filling and said ohmically heating; anddischarging molten glass continuously from said melting tank in accordance with the amount of the molten glass or the glass material supplied to said melting tank. 17. A method of manufacturing a substrate for an information recording medium, comprising steps of: manufacturing a glass blank by a glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising: a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material; at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; and at least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank; wherein: every one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andgrinding/polishing a main surface of said glass blank to manufacture a substrate for an information recording medium; andwherein the electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 18. A method of manufacturing a substrate for an information recording medium, comprising steps of: manufacturing a glass blank by a glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising: a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material; at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; and at least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank; wherein: every one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank;grinding and/or polishing a main surface of said glass blank to form a substrate; andforming an information recording layer on said main surface of said substrate to produce an information recording medium; andwherein the electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 19. A method of manufacturing a substrate for a display, comprising steps of: manufacturing a glass blank by a glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising: a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material; at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; and at least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank; wherein: every one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andusing said glass blank to produce a substrate for a display; andwherein the electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 20. An optical component manufacturing method comprising steps of: manufacturing a glass blank by a glass manufacturing method for mass-producing glass with a glass melting furnace, said glass melting furnace comprising: a melting tank, at least a wall surface in contact with molten glass thereof being made of refractory material; at least one pair of electrodes placed so as to be in contact with said molten glass held in said melting tank for ohmically heating said molten glass held in said melting tank; and at least one metallic member, at least a surface of which is made of metal and placed so as to be substantially always in contact with said molten glass held in said melting tank; wherein: every one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andgrinding and/or polishing a main surface of said glass blank to form an optical component; andwherein the electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region. 21. A glass manufacturing method for mass-producing glass with a glass melting furnace by: filing a melting tank of said glass melting furnace with molten glass;ohmically heating said molten glass held in said melting tank by means of at least one pair of electrodes placed so as to be in contact with said molten glass; andplacing at least one metallic member, of which at least a surface is made of metal, to contact with said molten glass; whereinsaid placing is carried before the start of said mass producing of glass for every one of said at least one metallic member to be fixedly placed away from said at least one pair of electrodes in a low erosion region where erosion caused by increasing of cumulative contact between the molten glass held in said melting tank and the wall surface of said melting tank is estimated to be smaller then that of the other region at the end of said mass-producing of glass, substantially flush with the wall surface of said melting tank; andevery one of said at least one metallic member is, when said melting tank is filled with said molten glass, placed so as to be substantially always outside an electric current flowing region which is formed by said at least one pair of electrodes into said molten glass held in said melting tank; andthe electric current flowing region comprises: a first region in which a pair of the electrodes are immediately opposed to each other; anda second region up to 60 degrees upward and up to 30 degrees sideways and downward from the end of the electrodes from the first region.
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