| 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 | 制造凝固多孔粘结物的方法和装置 | CN200580005753.0 | 2005-02-22 | CN1922120A | 2007-02-28 | M·里高登; J·博尔德; S·R·布特勒; E·米拉蒙 |
| 本发明提供一种制造凝固多孔粘结物的方法,该方法包括如下步骤:(i)将粘结材料、水、发泡剂和任选的添加剂混合成坍落度为至少100mm的自由流动淤浆;随后(ii)注射和分布空气入步骤(i)的淤浆以形成多孔淤浆;随后(iii)浇铸步骤(ii)的该多孔淤浆;以及最后(iv)允许该多孔淤浆凝固。本发明也提供进行本发明的方法的装置。 | ||||||
| 2 | 制造凝固多孔粘结物的方法和装置 | CN200580005753.0 | 2005-02-22 | CN1922120B | 2010-06-09 | M·里高登; J·博尔德; S·R·布特勒; E·米拉蒙 |
| 本发明提供一种制造凝固多孔粘结物的方法,该方法包括如下步骤:(i)将粘结材料、水、发泡剂和任选的添加剂混合成坍落度为至少100mm的自由流动淤浆;随后(ii)注射和分布空气入步骤(i)的淤浆以形成多孔淤浆;随后(iii)浇铸步骤(ii)的该多孔淤浆;以及最后(iv)允许该多孔淤浆凝固。本发明也提供进行本发明的方法的装置。 | ||||||
| 3 | 由多个六角形单元构成的蜂窝结构体 | CN200780008897.0 | 2007-03-15 | CN101400426A | 2009-04-01 | 水野达司; 近藤寿治 |
| 本发明涉及一种由六角形单元和外周壁构成的蜂窝结构体。每个六角形单元都由六角形布置的六个单元壁围绕。单元壁分为标准单元壁和加强单元壁。每个加强单元壁的强度比每个标准单元壁的强度高。加强单元壁形成了强度加强区域。在蜂窝结构体的直径方向的截面上观察,强度加强区域中的每个部分大致为直线形状。强度加强区域中的每个部分的两端都与外周壁接触。 | ||||||
| 4 | 污染控制元件保持部件及污染控制装置 | CN200480024918.4 | 2004-08-27 | CN1846044A | 2006-10-11 | 金子信一; 宫坂宗树 |
| 一种污染控制元件保持或安装部件(2),其用于将污染控制元件(1)安装在外壳内,该部件(2)展现出良好的封装操作性,也就是在封装操作过程中不会与污染控制元件分离开,且在下列方面中的一个、一些或全部方面是优异的:抗热性、气压保持性及抗腐蚀性。该污染控制元件安装部件(1)包括含有纤维材料的衬垫(2),该衬垫具有这样的厚度,外部(2a)具有用来与外壳(4)接触的外围表面,而内部(2b)具有用来与污染控制元件(1)接触的内围表面。至少内部的内围表面(2b),且可选地是外部的外围表面(2a),浸渍有摩擦/粘合控制剂(3),使得外围表面与外壳(4)之间的摩擦系数低于内围表面与污染控制元件(1)之间的摩擦系数。该摩擦/粘合控制剂(3)能够在污染控制元件(1)的操作条件下分解并消散。 | ||||||
| 5 | CATLYTIC CONVERTERS HAVING NON-LINEAR FLOW CHANNELS | US15384335 | 2016-12-20 | US20170175609A1 | 2017-06-22 | MANSOUR MASOUDI |
| Disclosed is a honeycomb catalyst substrate core having geometrically non-linear flow channels. In an embodiment, the honeycomb catalyst substrate core includes helical flow channels. In another embodiment, the honeycomb catalyst substrate core includes sinusoidal flow channels. In yet another embodiment, the honeycomb catalyst substrate core includes helical plus sinusoidal flow channels. The honeycomb catalyst substrate core comprises a plurality of parallel non-linear flow channels formed along a longitudinal axis of symmetry of the catalyst substrate core, each non-linear flow channel configured such that a turbulent vortical flow occurs during engine exhaust gas flow. Also disclosed is a method for manufacturing a ceramic honeycomb having non-linear flow channels, comprising the steps extrusion soft ceramic material through a die whilst the die moves through six degrees of freedom along its axis of symmetry. Disclosure includes a method for manufacturing a ceramic honeycomb having non-linear flow channels using three-dimensional printing. | ||||||
| 6 | Method of fabricating plaster board | US10508885 | 2003-03-25 | US07686902B2 | 2010-03-30 | Tatsukazu Kimura; Norio Tsuno; Seigo Ishibashi; Hirokuni Tani; Kenichiro Osawa |
| There is provided a lightweight plaster board having a cellular porous plaster core, excellent in adhesion to a covering base paper for a plaster board, free from dry-out in side edge parts of the plaster board, and with no disadvantage in workability for driving a nail into the plaster board. The plaster board includes a plaster core having a front surface, a back surface, and four side surfaces, and at least one covering base paper that covers the front surface, the back surface, and the at least two opposite side surfaces of the plaster core. The plaster core includes one or more hard edge parts each including one of the side surfaces covered with the covering base paper, one or more high-density parts including the front surface or the back surface, not including the side surface covered with the covering base paper, and having a density substantially equal to the density of the hard edge part, and a low-density part having a density less than the densities of the hard edge part and the high-density part and contacting with the hard edge part and the high-density part. The hard edge part does not include a position in which a nail is driven. | ||||||
| 7 | APPARATUS FOR MANUFACTURING SET CELLULAR CEMENT | US12192425 | 2008-08-15 | US20080310248A1 | 2008-12-18 | Michel Rigaudon; Jorg Bold; Steven Roy Butler; Eric Millamon |
| A process for manufacturing set cellular cement, including the steps of: (i) mixing cementitious material, water, foaming agent and optionally additives into a free flowing slurry having a slump of at least 100 mm; subsequently (ii) injecting and distributing air into the slurry of step (i) to form a cellular slurry; subsequently (iii) casting the cellular slurry of step (ii); and finally allowing the cellular slurry to set. And, an apparatus for carrying out the process. | ||||||
| 8 | Process And Apparatus For Manufacturing Set Cellular Cement | US10906143 | 2005-02-04 | US20050219938A1 | 2005-10-06 | Michel Rigaudon; Jorg Bold; Steven Butler; Eric Millamon |
| A process for manufacturing set cellular cement, including the steps of: (i) mixing cementitious material, water, foaming agent and optionally additives into a free flowing slurry having a slump of at least 100 mm; subsequently (ii) injecting and distributing air into the slurry of step (i) to form a cellular slurry; subsequently (iii) casting the cellular slurry of step (ii); and finally allowing the cellular slurry to set. And, an apparatus for carrying out the process. | ||||||
| 9 | Particulates and methods of utilizing these particulates in subterranean applications | US10631954 | 2003-07-30 | US20050022991A1 | 2005-02-03 | M. Rao |
| The present invention involves reduced specific gravity particulates and their use in subterranean applications such as production enhancement and completion. One embodiment of the present invention provides particulates comprising silica and an aluminum oxide and at least one void and having a specific gravity of less than about 2.2, a particle size of 8 U.S. Mesh or smaller, and a substantially spherical shape. Other embodiments of the present invention provide for using such particulates in subterranean operations such as fracturing and gravel packing. | ||||||
| 10 | Durable porous article of manufacture and a process to create same | US09662985 | 2000-09-15 | US06443258B1 | 2002-09-03 | Dean L. Putt; Marsha Stalker Bischel; Anthony L. Wiker; Andrea M. Moser |
| An acoustically absorbent porous panel formed from a cured aqueous foamed cementitious material comprising on a wet basis of about 53% to about 68% by weight cement, about 17% to about 48% by weight water, about 0.05% to about 5% by weight fiber, and about 0.01% to about 10% by weight surfactant. The panel also has pores distributed within the cured material comprising about 75% to about 95% by volume of the material. The cement-based, foamed panel provides good acoustical performance with enhanced durability and moisture resistance. | ||||||
| 11 | FABRICATION OF DUAL STRUCTURE CERAMICS BY A SINGLE STEP PROCESS | US13504172 | 2010-10-20 | US20120225270A1 | 2012-09-06 | Francesco Basoli; Silvia Licoccia; Eric D. Wachsman; Enrico Traversa |
| The subject invention discloses a method for the preparation of a dual structure cellular ceramic object where a dispersion of a ceramic precursor a chain-growth or step-growth polymer precursor and a solvent is heated to a first temperature at a first rate followed by heating to a second temperature at a second rate and holding the temperature to form a sintered dual structure cellular ceramic object which is then cooled at a third rate to room temperature. The dual structure cellular ceramic object has a dense surface layer over at least a portion of the object that abruptly yet smoothly and continuously transitioning into a porous ceramic. | ||||||
| 12 | Process and apparatus for manufacturing set cellular cement | US10906143 | 2005-02-04 | US08119207B2 | 2012-02-21 | Michel Rigaudon; Jorg Bold; Steven Roy Butler; Eric Millamon |
| A process for manufacturing set cellular cement, including the steps of: (i) mixing cementitious material, water, foaming agent and optionally additives into a free flowing slurry having a slump of at least 100 mm; subsequently (ii) injecting and distributing air into the slurry of step (i) to form a cellular slurry; subsequently (iii) casting the cellular slurry of step (ii); and finally allowing the cellular slurry to set. And, an apparatus for carrying out the process. | ||||||
| 13 | Methods of using particulates in subterranean operations | US12870220 | 2010-08-27 | US08047289B2 | 2011-11-01 | M. Vikram Rao |
| Among the methods described herein are methods using low-specific gravity particulates wherein the particulates comprise silica and an aluminum oxide in an amount of about 0.1% to about 25% by weight and having at least one void, a specific gravity of less than about 2.2, a particle sized of 8 U.S. Mesh or smaller, and a substantially spherical shape. | ||||||
| 14 | Methods of Making Particulates for Use in Subterranean Applications | US12869863 | 2010-08-27 | US20100320652A1 | 2010-12-23 | M. Vikram Rao |
| Among the methods described herein are methods of making a low-specific gravity particulate including the steps of: (a) providing combustion products of carbonaceous materials comprising silica and an aluminum oxide, (b) mixing the combustion products with a binder to create a pelletizable mixture; (c) pelletizing the combustion products of carbonaceous materials to create a pellet, and (d) sintering the combustion products of carbonaceous materials to create a particulate comprising silica and an aluminum oxide in an amount of about 0.1% to about 25% by weight and having at least one void, a specific gravity of less than about 2.2, a particle size of 8 U.S. Mesh or smaller, and a substantially spherical shape. | ||||||
| 15 | Gypsum board | US11508002 | 2006-08-22 | US07691467B2 | 2010-04-06 | Tatsukazu Kimura; Norio Tsuno; Seigo Ishibashi; Hirokuni Tani; Kenichiro Osawa |
| A plaster board including a plaster core having a front surface, a back surface, two opposite side surfaces and two opposite end surfaces and a covering base paper covering the front surface, back surface, and two opposite side surfaces, which core includes high-density hard edge parts including the two opposite side surfaces, at least one high-density part including the front or back surface, and having a density substantially equal to densities of the high-density hard edge parts, and a central low-density part having a density less than the densities of the high-density hard edge parts and the high-density part and being inscribed in the high-density hard edge parts and the high-density part, wherein each of the high-density hard edge parts is formed so as not to be present in the nailing area along longitudinal directions of the board in which a nail for fixing the board is driven. | ||||||
| 16 | HONEYCOMB STRUCTURE BODY COMPOSED OF A PLURALITY OF HEXAGONAL CELLS | US12209347 | 2008-09-12 | US20090011181A1 | 2009-01-08 | Tatsuji MIZUNO; Toshiharu Kondo |
| A honeycomb structure body is composed of hexagonal cells and an outer peripheral wall. Each hexagonal cell is surrounded by six cell walls of a hexagonal arrangement. The cell walls are divided into standard cell walls and reinforced cell walls. The strength of each reinforced cell wall is stronger than that of each standard cell wall. The reinforced cell walls form a strength reinforced area. Each component in the strength reinforced area has an approximate straight-line shape observed on a cross section in the diameter direction of the honeycomb structure body. Both ends of each component in the strength reinforced area are contacted to the outer peripheral wall. | ||||||
| 17 | Honeycomb structure producing method, and honeycomb structure | US10509866 | 2003-04-11 | US07276276B2 | 2007-10-02 | Yasushi Noguchi; Tomoo Nakamura |
| In a method for producing a honeycomb structure 20 which comprises disposing a material for forming outer wall 11 on the outer peripheral surface 3 of a cell structure 1 having a plurality of cells serving as fluid flowing channels to produce a cell structure being provided with a material for forming outer wall 10 and firing the resulting cell structure being provided with a material for forming outer wall 10, wherein a cell structure being provided with a material for forming outer wall 10 in which the absolute value of the difference between the volumetric shrinkage percentage (firing shrinkage percentage) before and after firing of the cell structure 1 and the firing shrinkage percentage of the material for forming outer wall 11 is not more than 0.5% is produced and fired. There is provided a method for producing a honeycomb structure which comprises providing an outer wall on the outer peripheral surface and firing it, according to which the outer wall hardly cracks during firing and high-strength and large-sized honeycomb structure can be produced, and further provided is a high-strength and large-sized honeycomb structure in which the outer wall hardly cracks during firing. | ||||||
| 18 | Honeycomb structure producing method, and honeycomb structure | US10509866 | 2003-04-11 | US20050255288A1 | 2005-11-17 | Yasushi Noguchi; Tomoo Nakamura |
| In a method for producing a honeycomb structure 20 which comprises disposing a material for forming outer wall 11 on the outer peripheral surface 3 of a cell structure 1 having a plurality of cells serving as fluid flowing channels to produce a cell structure being provided with a material for forming outer wall 10 and firing the resulting cell structure being provided with a material for forming outer wall 10, wherein a cell structure being provided with a material for forming outer wall 10 in which the absolute value of the difference between the volumetric shrinkage percentage (firing shrinkage percentage) before and after firing of the cell structure 1 and the firing shrinkage percentage of the material for forming outer wall 11 is not more than 0.5% is produced and fired. There is provided a method for producing a honeycomb structure which comprises providing an outer wall on the outer peripheral surface and firing it, according to which the outer wall hardly cracks during firing and high-strength and large-sized honeycomb structure can be produced, and further provided is a high-strength and large-sized honeycomb structure in which the outer wall hardly cracks during firing. | ||||||
| 19 | Composite structure with foamed cementitious layer | US09663288 | 2000-09-15 | US06613424B1 | 2003-09-02 | Dean L. Putt; Peter A. Christie; Andrea M. Moser; Marsha Stalker Bischel; Anthony L. Wiker |
| The present invention provides for an acoustically absorbent porous panel that is both rigid and resistant to sagging caused by moisture. The acoustically absorbent porous panel is comprised of at least two layers. The first layer is a facing layer formed from a cured aqueous foamed cementitious material. The foamed cementitious material comprises on a wet basis about 53% to about 68% by weight cement, about 17% to about 48% by weight water, about 0.05% to about 5% by weight fiber, and about 0.01% to about 10% by weight surfactant. Additionally, pores distributed within the cured material comprising about 75% to about 95% by volume of the material. The second layer is a backing layer that is affixed to the facing layer. | ||||||
| 20 | 오염 조절 요소의 유지재 및 오염 조절 장치 | KR1020067004106 | 2004-08-27 | KR1020060123716A | 2006-12-04 | 가네꼬,시니찌; 미야사까,무네끼 |
| A pollution control element-retaining or -mounting member (2) for mounting a pollution control element (1) within a casing and that shows good canning operability, that is not separated from the pollution control element during the canning operation, and that is excellent in one, some or all of heat resistance, an aerial pressure retaining property and erosion resistance. The pollution control element- mounting member (1) comprises a mat (2) containing fiber material, with the mat having a thickness with an external portion (2a) having an external peripheral surface for contacting the casing (4) and an internal portion (2b) having an internal peripheral surface for contacting the pollution control element (1). At least the internal peripheral surface of the internal portion, and optionally the external peripheral surface of the external portion, (2a) is impregnated with a friction/adhesion controlling agent (3) such that the coefficient of friction between the external peripheral surface and the casing (4) is lower than the coefficient of friction between the internal peripheral surface and the pollution control element (1). The friction/adhesion controlling agent (3) can decompose and dissipate under operating conditions of the pollution control element (1). | ||||||
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