121 |
Joining method of graphite and metal |
JP20133893 |
1993-08-13 |
JP2720762B2 |
1998-03-04 |
TASHIRO MINORU; KASAHARA AKIHIKO |
|
122 |
Method of manufacturing a ceramic assembly |
JP28832493 |
1993-11-17 |
JP2713688B2 |
1998-02-16 |
俊広 吉田; 敬一郎 渡邊 |
|
123 |
Bonded material, its production and brazing material for ceramic member |
JP8195496 |
1996-03-12 |
JPH09249462A |
1997-09-22 |
MAKINO TAKUMA; SHINKAI MASAYUKI |
PROBLEM TO BE SOLVED: To obtain a bonded material capable of improving corrosion resistance to a halogen-based gas by bonding a ceramic member to another member through a specific brazing material. SOLUTION: One or more metals selected from copper, aluminum and nickel are mixed with 1-10wt.% of beryllium and optionally <=50wt.% of at least one selected from among Si, Al, Cu and In to give a brazing material. The brazing material having 0.5-5μm thickness is laid between a ceramic member and another member and is pressurized while heating at a temperature equal to or lower than the liquid phase line temperature of the brazing material to bond the ceramic member to another member. |
124 |
Diamond assembly and its production |
JP22296596 |
1996-08-26 |
JPH09175873A |
1997-07-08 |
FURAIDORU SHIIGUFURIIITO NEMEI; BURATSUDORII AARU UIRIAMUZU |
PROBLEM TO BE SOLVED: To provide a diamond assembly improved in adhesive force required for the uses of high temperature and high pressure by interposing a metal filler material between a diamond film and a non-diamond flange formed on a part of a wall constituting a device.
SOLUTION: A non-diamond flange 4 comprising one or more metals selected from among Mo, W, Nb, Pt, Re and Ta and having a circular upper connection part 6 is formed on the surface of a part of a wall constituting a pressure or vacuum device 2. A metal filler material 10 comprising the alloy consisting of 15.5% of Ni, 0.75% of Mo, 8.2%, of V and 82% of Au or a silver solder and having a melting point of ≥45o°C is adhered to the flange 4. A diamond film 8 is disposed on the metal filler material to form the assemble. The assemble is heated at the melting point of the metal filler material or at a higher temperature and subsequently cooled to blaze the diamond film 8 to the flange 4 in a sealed state.
COPYRIGHT: (C)1997,JPO |
125 |
Bonded material, corrosion-resistant bonding material and production of bonded material |
JP2483596 |
1996-01-19 |
JPH08277171A |
1996-10-22 |
FUJII TOMOYUKI; USHIGOE RYUSUKE |
PURPOSE: To improve the wettability and the bonding strength of an aluminum nitride part and improve the corrosion resistance of a bonded material to a halogen-based corrosive gas in the production of a bonded material of an aluminum nitride part and a metallic part or a ceramic part by soldering. CONSTITUTION: This bonded material of an aluminum nitride part 8 and another part 7 made of ceramic or metal contains a bonding layer 23F formed between the parts 8 and 7. The bonding layer 23F contains a continuous phase 26 containing a metal selected from among popper, aluminum and nickel as at least the main component of the phase and further contains >=10wt.% of one or more kinds of active metals selected from among magnesium, titanium, zirconium and hafnium. |
126 |
Jig for producing ceramics joined body and production of ceramics joined body using the jig |
JP5017194 |
1994-03-22 |
JPH07257982A |
1995-10-09 |
YOSHIDA TOSHIHIRO; WATANABE KEIICHIRO |
PURPOSE:To prevent the mispositioning of members in sintering by using a jig with specified structure to joint a ceramics perforated plate and a ceramics tubular body. CONSTITUTION:A tubular body 2 made of a ceramics sintered body is inserted into each through-hole 3 of the perforated plate 1 made of a ceramics unsitered body having plural through-holes 3, the tubular body 2 is erected vertically to the floor to position the plate 1 at the upper and lower ends of the tubular body 2, and the assembly is sintered and integrally joined by utilizing the difference in shrinkage rate in sintering between both members. In this case, a jig 6 with the following structure is used. Namely, the jig consists of an end part 13 to be inserted into the jig fixing hole 12 preformed in the plate 1 and having an outer diameter slightly smaller than the diameter of the hole 12 and a barrel part 14 having an outer diameter larger than the diameter of the hole 12, the end part 13 and barrel part 14 are separably combined at the engaging part 16 when the end and barrel parts are engaged without being restricted by each other, and the jig is integrated with the ceramics joined body after the joining is completed. |
127 |
Manufacture of joining body for ceramics and metallic material |
JP28178093 |
1993-10-15 |
JPH07112330A |
1995-05-02 |
YANO TETSUO; OYA TOSHIHIKO; YONEDA MICHIFUMI; UCHIUMI AKIHIRO; KATSUMURA MUNEHIDE; MATSUDA JUN |
PURPOSE:To efficiently manufacture a joining body without lowering of characteristics and deformation for materials due to joining by radiating laser beam on a ceramics surface so as to deposit the metallic element of a ceramics component on its irradiated part, and joining metallic materials together through this metallic layer. CONSTITUTION:Argon gas is led to flow into a vacuum container after both joining samples 7, 8 are mounted into a joining jig 9 in the vacuum container 1 having an exhaust system 2 to keep its inside under vacuum and the degree of vacuum in the vacuum container is set by exhaust to approximately 5X10<-6>Torr with the exhaust system 2. A laser beam 3 is radiated on the joining sample 7 through a condensing lens 4 so as to deposit the metallic element of a ceramics component on the irradiated part after argon gas is ionized by an ion beam generator 5 and radiated on both joining samples 7, 8. Next, the joining samples 7, 8 are brought in contact with each other and pressurized by the joining jig 9, and heated at a low temperature by irradiation of the ion beam 6. By this process, the joining body for ceramics having the strong joining strength and metallic materials can be formed at a low temperature. |
128 |
a circuit board |
JP16178386 |
1986-07-11 |
JPH0680873B2 |
1994-10-12 |
SATO HIDEKI; MIZUNOYA NOBUYUKI |
|
129 |
JPH0573714B2 - |
JP21486485 |
1985-09-30 |
JPH0573714B2 |
1993-10-14 |
IWAMOTO SHINYA; UMESAKI NORIMASA; HIDAKA HIROAKI; IKUHARA YUKIO |
|
130 |
JPH0364473B2 - |
JP18970586 |
1986-08-14 |
JPH0364473B2 |
1991-10-07 |
GOTSUTOFURIIDO KUREMERU; MARUTEIN BARUTO |
|
131 |
JPH03501664A - |
JP50854988 |
1988-10-24 |
JPH03501664A |
1991-04-11 |
|
|
132 |
JPH0132188B2 - |
JP15494581 |
1981-10-01 |
JPH0132188B2 |
1989-06-29 |
HARUTOMUUTO RUURAIHI; FURANSHISUKO YOAHIMU DEIASU; ASUHOTSUKU KUMAARU GUPUTA; ERUNEE JARUMACHI; MARIAN KAMUPERU; RUDORUFU MYUNTSUERU; ARISUCHIDESU NAOMIDEISU |
|
133 |
Large format ceramic tile |
JP18970586 |
1986-08-14 |
JPS62128976A |
1987-06-11 |
GOTSUTOFURIIDO KUREMERU; MARUTEIN BARUTO |
|
134 |
Method for joining ceramic to metal, and sealing structure thereof |
US14719742 |
2015-05-22 |
US10103410B2 |
2018-10-16 |
Sundeep Kumar; Mohamed Rahmane; Hongbo Cao; Darren Michael Stohr; Raghavendra Rao Adharapurapu; Ravikumar Hanumantha |
A method for joining a metal component to a ceramic component is presented. The method includes disposing a metallic barrier layer on a metallized portion of the ceramic component, and joining the metal component to the metallized portion of the ceramic component through the metallic barrier layer. The metallic barrier layer comprises nickel and a melting point depressant. The metallic barrier layer is disposed by a screen printing process, followed by sintering the layer at a temperature less than about 1000 degrees Celsius. A sealing structure including a joint between a ceramic component and a metal component is also presented. |
135 |
Method for Joining Ceramics to Ceramics or Ceramics to Metals, and Apparatus |
US15864810 |
2018-01-08 |
US20180128403A1 |
2018-05-10 |
Frederick M. Mako, Jr.; Edward Jeffrey Cruz; Frederick M. Mako |
An assembly including a ceramic body. The assembly comprises a tungsten coupling attached to the ceramic body with a first joint that forms a first helium tight seal between the ceramic body and the tungsten coupling and where the first helium tight seal maintains its integrity at a temperature over 400° C. The assembly includes a metal body attached to the tungsten coupling with a second joint that forms a second helium tight seal between the metal body and the tungsten coupling and where the second helium tight seal maintains its integrity at a temperature over 400° C. A method. A mixture. A coupling. |
136 |
Method For Manufacture Of A Multi-Layer Plate Device |
US15419952 |
2017-01-30 |
US20170259364A1 |
2017-09-14 |
Alfred Grant Elliot; Brent Donald Alfred Elliot; Frank Balma; Richard Erich Schuster; Dennis George Rex; Alexander Veytser |
A method for the joining of ceramic pieces with a hermetically sealed joint comprising brazing a layer of joining material between the two pieces. The wetting and flow of the joining material is controlled by the selection of the joining material, the joining temperature, the joining atmosphere, and other factors. The ceramic pieces may be aluminum nitride and the pieces may be brazed with an aluminum alloy under controlled atmosphere. The joint material is adapted to later withstand both the environments within a process chamber during substrate processing, and the oxygenated atmosphere which may be seen within the shaft of a heater or electrostatic chuck. |
137 |
DIRECTLY INTEGRATED FEEDTHROUGH TO IMPLANTABLE MEDICAL DEVICE HOUSING |
US15476716 |
2017-03-31 |
US20170203107A1 |
2017-07-20 |
Jacob Markham; Ulrich Hausch |
One aspect provides an implantable medical device with a housing having an opening with an opening width. A feedthrough is provided, including an insulator having a bottom surface and side surfaces and having an insulator width between opposing side surfaces that is greater than the opening width. A sinter joint is between at least one of the bottom surface, top surface, and side surfaces of the insulator and the housing which hermetically seals the insulator to the housing without an intervening ferrule. |
138 |
Low temperature method for hermetically joining non-diffusing ceramic materials |
US14292804 |
2014-05-30 |
US09624137B2 |
2017-04-18 |
Alfred Grant Elliot; Brent Donald Alfred Elliot; Frank Balma; Richard Erich Schuster; Dennis George Rex; Alexander Veytser |
A method for the joining of ceramic pieces with a hermetically sealed joint comprising brazing a layer of joining material between the two pieces. The wetting and flow of the joining material is controlled by the selection of the joining material, the joining temperature, the joining atmosphere, and other factors. The ceramic pieces may be on a non-diffusable type, such as aluminum nitride, alumina, beryllium oxide, and zirconia, and the pieces may be brazed with an aluminum alloy under controlled atmosphere. The joint material is adapted to later withstand both the environments within a process chamber during substrate processing, and the oxygenated atmosphere which may be seen within the shaft of a heater or electrostatic chuck. |
139 |
Multi-Layer Plate Device |
US15065500 |
2016-03-09 |
US20170036285A1 |
2017-02-09 |
Alfred Grant Elliot; Brent Donald Alfred Elliot; Frank Balma; Richard Erich Schuster; Dennis George Rex; Alexander Veytser |
A method for the joining of ceramic pieces with a hermetically sealed joint comprising brazing a continuous layer of joining material between the two pieces. The wetting and flow of the joining material is controlled by the selection of the joining material, the joining temperature, the time at temperature, the joining atmosphere, and other factors. The ceramic pieces may be aluminum nitride and the pieces may be brazed with an aluminum alloy under controlled atmosphere. The joint material is adapted to later withstand both the environments within a process chamber during substrate processing, and the oxygenated atmosphere which may be seen within the shaft of a heater or electrostatic chuck. |
140 |
SIC MATRIX FUEL CLADDING TUBE WITH SPARK PLASMA SINTERED END PLUGS |
US15225127 |
2016-08-01 |
US20160358673A1 |
2016-12-08 |
PENG XU; EDWARD J. LAHODA; LARS HALLSTADIUS; JOON HYUNG CHOI; SHINICHI HIGUICHI; FUMIHISA KANO |
A method of providing an end-capped tubular ceramic composite for containing nuclear fuel (34) in a nuclear reactor involves the steps of providing a tubular ceramic composite (40), providing at least one end plug (14, 46, 48), applying (42) the at least one end plug material to the ends of the tubular ceramic composite, applying electrodes to the end plug and tubular ceramic composite and applying current in a plasma sintering means (10, 50) to provide a hermetically sealed tube (52). The invention also provides a sealed tube made by this method. |