| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 融雪破冰磁铁矿石沥青混凝土表面层及其施工方法 | CN200910219527.2 | 2009-12-16 | CN101748673B | 2011-05-11 | 沙爱民; 郭德栋; 胡力群; 张成; 裴建中 |
| 一种具备融雪破冰功能的磁铁矿石沥青混凝土表面层,由集料100份、矿粉2~6份、沥青2~6份,集料是由磁铁矿石集料10~75份、普通集料25~90份配比组成。施工方法由原路面处理、洒布黏层油、拌和摊铺、压实、质量检验组成,铺筑成厚度为2~6cm的磁铁矿石沥青混凝土表面层。本发明磁铁矿石沥青混凝土表面层经过试验,结果表明,该结构层各项路用性能指标完全符合交通部部颁标准要求,而且其微波发热能力极强。本发明磁铁矿石沥青混凝土表面层具有路用性能良好、施工简便、成本低、安全环保等优点,可广泛应用于桥梁、机场道路、城市道路和高速公路等,在微波作用下,可实现快速发热融雪破冰。 | ||||||
| 2 | 无机保温金属饰面一体型防火墙面型材及其制备方法 | CN200910064337.8 | 2009-03-06 | CN101503903B | 2010-12-01 | 王艳锦; 王建春; 王博儒; 张春山; 李建军; 王博征 |
| 本发明涉及一种无机保温金属饰面一体型防火墙面型材及其制备方法,该墙面型材具有保温层和饰面层,保温层是由无机保温轻骨料与浆料混合压制成型,饰面层采用金属薄板,保温层与饰面层之间采用胶粘剂粘合压制成型为一体结构。该墙面型材的保温层是由多种天然无机矿物质复合材料组合配比而成,因而具有无毒、无味、不腐、不燃、耐酸、耐碱、隔热保温等多种良好性能,是一种比较理想的绿色环保建筑材料,并且采用金属饰面,不但具有良好的阻燃防火、防水,防开裂功能,使墙体和保温层得到最为理想的防护,而且具有高档华贵、装饰美化环境的感观效果。 | ||||||
| 3 | 建筑物保温外墙装饰砖 | CN200810231496.8 | 2008-12-24 | CN101475344B | 2012-01-04 | 焦安亮; 胡昌元; 黄延铮; 周申彬; 贾飞宏 |
| 本发明涉及一种安装在建筑物外墙上不仅能够起到保温,而且还具有装饰效果的建筑物保温外墙装饰砖,包括保温板材、保温板材上的装饰面砖,装饰面砖与保温板材间相互连接,在装饰面砖与保温板材间设有网格纤维布,保温板材由下列各原料按重量份数制成:聚苯颗粒50-70份、膨胀珍珠岩20-30份、浮石粉末10-20份、水泥10-20份、石膏粉5-15份、蛭石粉5-10份、细砂5-7份、粉煤灰10-15份、纤维素醚2-5份、硼砂2-3份、石英粉3-5份,将保温板材原料加入水后搅拌制成保温板材浆体,倒入放有蛇形锚固件的模具内,在保温板材浆体上面粘贴装饰面砖,凝固后为建筑物保温外墙装饰板材,具有重量轻、保温效果好、施工方便、保温装饰一体化、安全可靠、装饰性强的优点。 | ||||||
| 4 | 建筑物保温外墙装饰砖 | CN200810231496.8 | 2008-12-24 | CN101475344A | 2009-07-08 | 焦安亮; 胡昌元; 黄延铮; 周申彬; 贾飞宏 |
| 本发明涉及一种安装在建筑物外墙上不仅能够起到保温,而且还具有装饰效果的建筑物保温外墙装饰砖,包括保温板材、保温板材上的装饰面砖,装饰面砖与保温板材间相互连接,在装饰面砖与保温板材间设有网格纤维布,保温板材由下列各原料按重量份数制成:聚苯颗粒50-70份、膨胀珍珠岩20-30份、浮石粉末10-20份、水泥10-20份、石膏粉5-15份、蛭石粉5-10份、细砂5-7份、粉煤灰10-15份、纤维素醚2-5份、硼砂2-3份、石英粉3-5份,将保温板材原料加入水后搅拌制成保温板材浆体,倒入放有蛇形锚固件的模具内,在保温板材浆体上面粘贴装饰面砖,凝固后为建筑物保温外墙装饰板材,具有重量轻、保温效果好、施工方便、保温装饰一体化、安全可靠、装饰性强的优点。 | ||||||
| 5 | 融雪破冰磁铁矿石沥青混凝土表面层及其施工方法 | CN200910219527.2 | 2009-12-16 | CN101748673A | 2010-06-23 | 沙爱民; 郭德栋; 胡力群; 张成; 裴建中 |
| 一种具备融雪破冰功能的磁铁矿石沥青混凝土表面层,由集料100份、矿粉2~6份、沥青2~6份,集料是由磁铁矿石集料10~75份、普通集料25~90份配比组成。施工方法由原路面处理、洒布黏层油、拌和摊铺、压实、质量检验组成,铺筑成厚度为2~6cm的磁铁矿石沥青混凝土表面层。本发明磁铁矿石沥青混凝土表面层经过试验,结果表明,该结构层各项路用性能指标完全符合交通部部颁标准要求,而且其微波发热能力极强。本发明磁铁矿石沥青混凝土表面层具有路用性能良好、施工简便、成本低、安全环保等优点,可广泛应用于桥梁、机场道路、城市道路和高速公路等,在微波作用下,可现实快速发热融雪破冰。 | ||||||
| 6 | 无机保温金属饰面一体型防火墙面型材及其制备方法 | CN200910064337.8 | 2009-03-06 | CN101503903A | 2009-08-12 | 王艳锦; 王建春; 王博儒; 张春山; 李建军; 王博征 |
| 本发明涉及一种无机保温金属饰面一体型防火墙面型材及其制备方法,该墙面型材具有保温层和饰面层,保温层是由无机保温轻骨料与浆料混合压制成型,饰面层采用金属薄板,保温层与饰面层之间采用胶粘剂粘合压制成型为一体结构。该墙面型材的保温层是由多种天然无机矿物质复合材料组合配比而成,因而具有无毒、无味、不腐、不燃、耐酸、耐碱、隔热保温等多种良好性能,是一种比较理想的绿色环保建筑材料,并且采用金属饰面,不但具有良好的阻燃防火、防水,防开裂功能,使墙体和保温层得到最为理想的防护,而且具有高档华贵、装饰美化环境的感观效果。 | ||||||
| 7 | Surface treating agent for plating and base material with the plating adhered thereto | US08638170 | 1996-04-26 | US06171710B2 | 2001-01-09 | Masayuki Ogino; Shigehiko Hayashi; Masahito Kawahara; Kazuo Goto; Toru Noguchi; Yoshio Yamaguchi |
| A layer is provided for bonding a conductive plating to a substrate which substrate normally does not provide firm bonding of plating directly thereto. The bonding layer forms a matrix in which are dispersed ultrafine metal particles. The bonding layer is formed in situ on the substrate surface with the metal particles being maintained unaggregated in the matrix as it is formed on the surface. Plating subsequently formed on the outer surface of the bonding layer is effectively firmly bonded to the substrate through the intermediary of the matrix and metal particles distributed therein. The bonding layer includes a fixative formed of an organic compound including a metal and an organic solvent. The bonding layer may further include a film strengthener. | ||||||
| 8 | Honeycomb structure | US12497214 | 2009-07-02 | US08003191B2 | 2011-08-23 | Yutaka Ogura |
| Disclosed is a honeycomb structure capable of preventing the generation of cracks in buffer portions and preventing the honeycomb structure from being divided when an operation (regeneration) of burning collected particulate matters is repeated. A honeycomb structure 100 includes a plurality of honeycomb segments 4 having partition walls 2 separating and forming a plurality of cells, and protruding walls 3 which are provided so as to protrude externally from partition walls 2a forming side surfaces 5 of the segments. The plurality of honeycomb segments 4 are arranged adjacent to one another so that the side surfaces 5 of the honeycomb segments face each other with a predetermined distance being left therebetween, each buffer portion 11 is disposed between the adjacent honeycomb segments 4 to join the honeycomb segments 4 together, and an outer peripheral portion 13 is disposed on an outermost periphery 12. | ||||||
| 9 | HONEYCOMB STRUCTURE | US12497214 | 2009-07-02 | US20100035020A1 | 2010-02-11 | Yutaka OGURA |
| Disclosed is a honeycomb structure capable of preventing the generation of cracks in buffer portions and preventing the honeycomb structure from being divided when an operation (regeneration) of burning collected particulate matters is repeated. A honeycomb structure 100 includes a plurality of honeycomb segments 4 having partition walls 2 separating and forming a plurality of cells, and protruding walls 3 which are provided so as to protrude externally from partition walls 2a forming side surfaces 5 of the segments. The plurality of honeycomb segments 4 are arranged adjacent to one another so that the side surfaces 5 of the honeycomb segments face each other with a predetermined distance being left therebetween, each buffer portion 11 is disposed between the adjacent honeycomb segments 4 to join the honeycomb segments 4 together, and an outer peripheral portion 13 is disposed on an outermost periphery 12. | ||||||
| 10 | Method for coating a non-wetting fluidizable and material onto a substrate | US494125 | 1995-06-23 | US6123797A | 2000-09-26 | Aleksander J. Pyzik; Jack J. Ott; Harold E. Rossow; Uday V. Deshmukh |
| A method of coating a fluidizable material onto a surface of a substrate, wherein the substrate is not wettable by the fluidizable material includes depositing a layer of powder particles on the surface of the substrate, the powder particles being wettable by the fluidizable material; contacting the fluidizable material to the layer of powder particles; and allowing the fluidizable material to wick between the powder particles and to contact the surface of the substrate.The method of the invention provides a method which requires little or no binders or organic solvents, is applicable to many different ceramic-metal formulations, allows easy control of the thickness of the tape, forms fairly dense tapes so that little or no shrinkage occurs upon densification at elevated temperatures, and does not require undesirably high processing temperatures. | ||||||
| 11 | Surface treating agent for plating and base material adhered therewith | JP4549196 | 1996-02-06 | JPH0912385A | 1997-01-14 | OGINO MASAYUKI; HAYASHI SHIGEHIKO; KAWAHARA MASATO; GOTO KAZUO; NOGUCHI TORU; YAMAGUCHI YOSHIO |
| PROBLEM TO BE SOLVED: To obtain improved adhesive power by incorporating >=1 kinds of superfine metallic particles selected from Au, Pt, Pd, Rh, Ag, Ni, a binder consisting of an org. compd. contg. metals for fixing these particles and an org. solvent. SOLUTION: A high-polymer material, such a 'Nylon 11 (R)', is heated and melted under vacuum by a vacuum vapor deposition device and a vapor deposited high- polymer film is formed on a substrate. Next, >=1 kinds of the metals among Au, Pt, Pd, Rh, etc., are heated and melted under vacuum and the vapor deposited metallic films are formed on the high-polymer layers, by which the composite of the superfine metallic particles and the high polymer having a particle size of about 1 to 100m is produced. This composite is melted in a metacresol, etc., and is made into a paste form and thereafter, the binder, such as tetrabutoxy titanium, is added thereto at about 0.1 to 10mol per 1mol of the metals and a film reinforcing material, such as polysiloxane, at about 0.05 to 5mol and if necessary, a viscosity control agent, such as ethyl cellulose, by which the surface treating agent for plating is obtd. This treating agent is then applied on a base material and is fired at about 300 to 800 deg.C after drying, by which metal oxide is obtd. and the layers to be plated are formed. | ||||||
| 12 | HONEYCOMB STRUCTURE | EP09251777.0 | 2009-07-10 | EP2151553B1 | 2016-04-20 | Ogura, Yutaka |
| 13 | Surface treating agent for plating and base material with the plating adhered thereto | EP96302993.9 | 1996-04-29 | EP0739996B1 | 2002-02-27 | Ogino, Masayuki; Hayashi, Shigehiko; Kawahara, Masahito; Goto, Kazuo; Noguchi, Toru; Yamaguchi, Yoshio |
| 14 | Verfahren zum Abdichten keramischer Wärmetauscher | EP87116900.9 | 1987-11-17 | EP0272451A1 | 1988-06-29 | Linsner, Otmar; Berroth, Karl, Dr. |
Keramische Wärmetauscher mit engen Querschnitten werden dadurch abgedichtet, daß man auf der einen (später kalten) Seite des Wärmetauschers ein flüssiges Kunstharz einfüllt und dort einen Druck erzeugt, der höher ist als auf der anderen (später heißen) Seite des Wärmetauschers, man das überschüssige Harz entfernt und das Kunstharz aushärtet. Das Verfahren eignet sich insbesondere für keramische Wärmetauscher aus Silciumitrid. In diesem Fall kann man vor der Behandlung mit dem flüssigen Kunstharz eine Suspension von fein verteiltem Schleifmittel in einer flüssigen Phase durch die später kalte Seite des Wärmetauschers pumpen, bis die beim Reaktionsbrand entstandenen Whisker aus Siliciumnitrid mechanisch entfernt sind, und dann den Wärmetauscher spülen und trocknen. |
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| 15 | 방수시트 및 이를 이용한 시공방법 | KR1020050101316 | 2005-10-26 | KR1020070041281A | 2007-04-18 | 강미연; 황선우 |
| 우수한 내구성, 신장성, 내후성, 내한성, 방수성을 가지는 자기접착력이 있는 방수시트가 제시되어 있다. 또한 간단한 시공방법에 의해서, 단기간에 저렴한 비용으로 우수한 방수를 효과를 얻을 수 있는 방수시트 시공방법이 제시되어 있다. 본 발명의 일 측면에 따르면, 부틸고무층, 상기 부틸고무층의 상부에 형성되는 아스팔트층, 상기 아스팔트층의 상부에 형성되는 폴리에스테르와 폴리에틸렌을 포함하는 필름층, 상기 필름층의 상부에 형성되는 프라이머층 및 상기 프라이머층 상부에 형성되는 우레탄층을 포함하는 방수시트가 제공된다. 방수시트, 부틸고무층, 아스팔트층, 프라이머층, 우레탄층 | ||||||
| 16 | 기판에의 비습윤성 유동성 물질의 피복방법, 세라믹 금속구조물의 제조방법, 다수의 세라믹체의 결합방법 및 이러한 방법에 의해 형성된 층상구조물 | KR1019970709645 | 1996-06-24 | KR100432075B1 | 2004-08-16 | 피직알렉산더제이; 로소우헤롤드이; 옷트잭제이; 데시무크우데이브이 |
| A method of coating a fluidizable material onto a surface of a substrate, wherein the substrate is not wettable by the fluidizable material includes depositing a layer of powder particles on the surface of the substrate, the powder particles being wettable by the fluidizable material; contacting the fluidizable material to the layer of powder particles; and allowing the fluidizable material to wick between the powder particles and to contact the surface of the substrate. The method of the invention provides a method which requires little or no binders or organic solvents, is applicable to many different ceramic-metal formulations, allows easy control of the thickness of the tape, forms fairly dense tapes so that little or no shrinkage occurs upon densification at elevated temperatures, and does not require undesirably high processing temperatures. | ||||||
| 17 | METHOD OF COATING, METHOD FOR MAKING CERAMIC-METAL STRUCTURES, METHOD FOR BONDING, AND STRUCTURES FORMED THEREBY | EP96923296.6 | 1996-06-24 | EP0833698B1 | 2002-08-14 | PYZIK, Aleksander, J.; ROSSOW, Harold, E.; OTT, Jack, J.; DESHMUKH, Uday, V. |
| A method, and the structure formed thereby, of coating a fluidizable material onto a surface of a substrate wherein the substrate is not wettable by the fluidizable material includes depositing a layer of powder particles on the surface of the substrate, the powder particles being wettable by the fluidizable material; contacting the fluidizable material to the layer of powder particles; and allowing the fluidizable material to wick between the powder particles and to contact the surface of the substrate. Another aspect is a method for making a ceramic-metal tape which includes depositing a layer of a non-wettable ceramic powder onto a solid form; depositing a layer of a wettable powder onto the layer of the non-wettable ceramic powder; contacting a metal to the layer of the wettable powder; heating the metal to a temperature in which the metal melts and wicks through the layer of the wettable powder, and cooling the metal-infiltrated structure to solidify the metal. Another aspect is a method for bonding ceramic bodies together and the layered structure formed therefrom. The method includes coating a surface of a first ceramic body with non-reactive powder particles and reactive powder particles; abutting a surface of a second ceramic body against the coated surface of the first ceramic body; contacting the coating between the first ceramic body and the second ceramic body with a metal; and heating the metal so that the metal infiltrates through the powder particles. | ||||||
| 18 | OBERFLÄCHENVEREDELTE BETONSTEINE, VERFAHREN ZUR HERSTELLUNG UND VERWENDUNG DERSELBEN | EP00965880.8 | 2000-08-17 | EP1204615A2 | 2002-05-15 | SCHULTZE-KRAFT, Andreas |
| Concrete blocks which are provided with a conventional cement bound, sanded or water-jet blasted finish have a porous surface which tends to become soiled with dirt, moss or oil patches. The invention provides concrete blocks with a highly stable and substantially chemically- resistant finish resembling that of natural stone, whereby the surface thereof is not porous and is therefore not susceptible to soiling through dirt, oil patches and moss. The finish is inseparably bound to the concrete block, and is essentially made up of a reaction resin which is used as a polymer bonding agent, in addition to recycled glass which is used as a filler. A substantial part of the recycled glass is provided with a colored elastic polyvinylacetate coating. Various methods make it possible to apply said surface finish before or after production of the concrete blocks. | ||||||
| 19 | METHOD AND COMPOSITION FOR ROUGHENING THE ROAD SURFACE | EP97911437.8 | 1997-10-28 | EP1023504B1 | 2001-06-13 | SPINOGLIO, Silvio |
| Laying method of the type in which: on the roadbed (1) a binding liquid or pasty layer (2) is laid, substantially made up of binding resin that sticks to the surface of the road carpet and subsequently hardens; on said liquid or pasty layer (2), before the hardening, an aggregate material layer in granules (3) is evenly laid, in such a way that once the hardening of said resin (2) has occurred, said aggregate material in granules (3) is strongly bound to the road carpet; the aggregate material in granules that has not been adequately fixed to the roadbed is removed; where: said aggregate material in granules is artificially produced; its granules are polygon-shaped with sharp corners; the constitutent material is a mixture of forsterite, spinel, magnesium chromate and iron in which the presence of A1203 for a value comprised between 5 % and 15 % preferably about 10/11 % is provided. In this way an optimal coating is obtained. | ||||||
| 20 | METHOD OF COATING, METHOD FOR MAKING CERAMIC-METAL STRUCTURES, METHOD FOR BONDING, AND STRUCTURES FORMED THEREBY | EP96923296.0 | 1996-06-24 | EP0833698A1 | 1998-04-08 | PYZIK, Aleksander, J.; ROSSOW, Harold, E.; OTT, Jack, J.; DESHMUKH, Uday, V. |
| A method, and the structure formed thereby, of coating a fluidizable material onto a surface of a substrate wherein the substrate is not wettable by the fluidizable material includes depositing a layer of powder particles on the surface of the substrate, the powder particles being wettable by the fluidizable material; contacting the fluidizable material to the layer of powder particles; and allowing the fluidizable material to wick between the powder particles and to contact the surface of the substrate. Another aspect is a method for making a ceramic-metal tape which includes depositing a layer of a non-wettable ceramic powder onto a solid form; depositing a layer of a wettable powder onto the layer of the non-wettable ceramic powder; contacting a metal to the layer of the wettable powder; heating the metal to a temperature in which the metal melts and wicks through the layer of the wettable powder, and cooling the metal-infiltrated structure to solidify the metal. Another aspect is a method for bonding ceramic bodies together and the layered structure formed therefrom. The method includes coating a surface of a first ceramic body with non-reactive powder particles and reactive powder particles; abutting a surface of a second ceramic body against the coated surface of the first ceramic body; contacting the coating between the first ceramic body and the second ceramic body with a metal; and heating the metal so that the metal infiltrates through the powder particles. | ||||||
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