| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | Verfahren zur stofflichen Verwertung von mit organischem Material verunreinigtem Gips | EP98103802.9 | 1998-03-04 | EP0864536B1 | 2003-05-28 | Demmich, Jörg, Dr.-Ing.; Weissflog, Eckhard, Dr.; Kempf, Wolf-Dieter, Dr. |
| 82 | Verfahren zur stofflichen Verwertung von mit organischem Material verunreinigtem Gips und seine Verwendung | EP98103802.9 | 1998-03-04 | EP0864536A1 | 1998-09-16 | Demmich, Jörg, Dr.-Ing.; Weissflog, Eckhard, Dr.; Kempf, Wolf-Dieter, Dr. |
Das Verfahren zur stofflichen Verwertung von mit organischem Material verunreinigtem Gips, insbesondere von Abfällen von Vollgipsplatten, Gipskarton- und/oder Gipsfaserplatten und/oder mineralisch gebundenen Holzspanplatten (z.B. Heraklit®-Platten) und/oder Abfallgipsen der Kraftwerksindustrie, denen gegebenenfalls andere kohlenstoff- und/oder gipshaltige Abfälle zugemischt wurden, erfolgt dadurch, daß diese Abfälle auf Körnungen von maximal 2 cm vorzerkleinert und unter geregelter Zufuhr von überschüssigem Sauerstoff bei Temperaturen von 450 bis 950°C zum Anhydrit gebrannt werden. |
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| 83 | Geopolymer-modified, gypsum-based construction material | EP93301837.6 | 1993-03-11 | EP0614858A1 | 1994-09-14 | Laney, Billy Eugene |
Geopolymer-modified gypsum construction materials. Compositions derived from combining geopolymer adhesive with conventional gypsum wallboard slurry formulations produce an interpenetrating network (IPN) which cures by loss of process water to a refractory solid having improved fire and water resistance. Geopolymer adhesive starting compositions include soluble and insoluble silicates, buffers and salts, and a chemical setting agent in aqueous suspension. |
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| 84 | Verfahren zur Herstellung eines nach dem Anmachen mit Wasser schnellerstarrenden hydraulischen Bindemittels | EP89110343.4 | 1989-06-08 | EP0347655B1 | 1993-08-11 | Koslowski, Thomas, Dr.; Ludwig, Udo, Prof. Dr.; Fröhlich, Alexander, Dr. |
| 85 | Verfahren zur Herstellung eines nach dem Anmachen mit Wasser schnellerstarrenden hydraulischen Bindemittels | EP89110343.4 | 1989-06-08 | EP0347655A3 | 1990-09-05 | Koslowski, Thomas, Dr.; Ludwig, Udo, Prof. Dr.; Fröhlich, Alexander, Dr. |
Verfahren zur Herstellung eines nach dem Anmachen mit Wasser schnellerstarrenden hydraulischen Bindemittels mit definierter Wasserfestigkeit der daraus hergestellten erhärteten Masse. Es wird als schnellerstarrende Komponente Calciumsulfat-Alphahalbhydrat in einer vorgegebenen Ausgangsmenge eingesetzt, dessen erhärtete Masse eine zeitabhängige Wasserfestigkeitskurve aufweist, die, ausgehend von einem hohen Frühfestigkeitswert der Schnellerstarrung, in den ersten achtundzwanzig Tagen eine negative Steigung besitzt. Dem Calciumsulfat-Alphahalbhydrat wird Hüttensand beigemischt. Die Menge an Hüttensand wird auf die Ausgangsmenge an Calciumsulfat-Alphahalbhydrat so abgestimmt, daß im Anschluß an die Schnellerstarrung kristalline Ettringitbildung sowie die Bildung von Calciumhydrosilikatphasen eintritt und die zeitabhängige Wasserfestigkeitskurve der erstarrten Mischung in den ersten achtundzwanzig Tagen überall eine positive Steigung aufweist. |
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| 86 | Water proof building material based on gypsum, containing calcium silicate, and method for its preparation | EP82100502 | 1982-01-26 | EP0065065A3 | 1983-01-26 | HILDEBRANDT, ULRICH, DR. PROF.; HOSE, HORST, DR. DIPL.-CHEM.; NEUMANN-VENEVERE, PETER, PROF. DR. ING. |
| 87 | 조강 시멘트들을 위한 저열 처리된 황산 칼슘들 및 일반 사용 | KR1020157025825 | 2014-02-18 | KR1020150144744A | 2015-12-28 | 오즈수트무스타파 |
| 본발명은포틀랜드(Portland) 또는 CEM 시멘트들로서 EN 및 ASTM 하에서분류된시멘트들의초기강도및 최종강도들을증가시키는것에관한것이고, 또한모든클링커를채택하는시멘트들및 응고최적화를위해황산칼슘들을채택하고생산을위한새로운방법을단지애세싱하여새로운시멘트들을구성하고형성물에단지새로운방법들을애세싱하고응고최적화를위해사용되는황산칼슘리소스들의함유에의해새로운시멘트들을구헝하는임의의종류들에관한것이다. 새로운황산칼슘리소스는더 낮은열들을채택하여얻어지고이러한입력은이들이선택된사용에가장효율적일수 있는상이한탈수레벨들에배열된다. 이들상이한탈수레벨들은탈수물또는반수화물들의중간상들로서불리고또는일수화물로서불린다. 본발명은기존의과학적기초에의해규정되지않았던잘 규정된반응도개념을명확히한다. 그결과, 알려진것보다훨씬높은초기강도들을가지는시멘트들이생산될수 있다. | ||||||
| 88 | 환원 슬래그 분말을 이용한 초속경성 수경결합재 및 그 제조방법 | KR1020100111768 | 2010-11-10 | KR1020120050329A | 2012-05-18 | 김진만; 곽은구; 오상윤; 김창학; 강기웅; 허동철 |
| PURPOSE: An ultra rapid-hardening hydraulic binder and a manufacturing method thereof are provided to enhance rapid hardening property and replace normal Portland cement. CONSTITUTION: An ultra rapid-hardening hydraulic binder using reduction slag powder includes reduction slag powder in which free-CaO does not exist. The reduction slag powder has a fineness of 3,000-12,000/g. The reduction slag powder comprises 40-60 weight% of CaO, 5-15 weight% of SiO2, and 15-25 weight% of Al2O3 and has no CaO. The reduction slag powder contains large amount of alumina and magnesia. The reduction slag powder largely contains Mayenite(C12A7, 12CaO·Al2O3) and B-C2S(Belite, B-2CaO·SiO2). A manufacturing method of the rapid hardening hydraulic binder using the reduction slag powder comprises next steps: scattering electric arc furnace to high pressure in a steel mill; quick freezing at room temperature; pulverizing the reduction slag into a fixed fineness; and mixing gypsum with the pulverized reduction slag. | ||||||
| 89 | 황토타일 제조방법 | KR1020100051776 | 2010-06-01 | KR1020110132005A | 2011-12-07 | 신현희 |
| PURPOSE: A loess tile manufacturing method is provided to naturally dry a molded loess tile, thereby preventing cracking of the tile. CONSTITUTION: Loess in a powder state, gypsum hemihydrate, micanite, and functional additives are mixed(S1). The 25 to 30 weight percent of water is added and mixed in the above mixed material for 15 to 30 minutes(S2). The mixed material is filled in a flexible silicon mold which is prepared in beforehand and molded in a flat shape(S3). A tile is separated from the silicon mold while being dried for 28 to 33 hours in a shaded drying room(S4). The functional additive is a retarder and gypsum hardener. | ||||||
| 90 | A METHOD OF INERTISING THE IMPURITIES IN PHOSPHOGYPSUM | PCT/IN2007000342 | 2007-08-08 | WO2008062430A2 | 2008-05-29 | KHADILKAR SHREESH ANANT; KARANDIKAR MANISH VASANT; ANIKODE PADMANABHAN RAMALINGAM; LELE PRADIP GOPAL; VAITY RINA SURESH; PATHAK ABHAY KANT |
| The invention pertains to a method of inertising free soluble impurities of phosphates and / or fluoride ions, in phosphogypsum, for use in commercial and industrial applications. The Phosphogypsum is pre-conditioned over an extended period of time separately or treated along with standard constituents by spraying, interblending or intergrinding during the process of manufacture, with alkyl, alkenyl and/or alkanol derivatives of ammonia, either individually or in combination with one another, to form stable intermediary phosphates and / or fluoride salts of the derivatives of ammonia. | ||||||
| 91 | STRUVITE-K AND SYNGENITE COMPOSITION FOR USE IN BUILDING MATERIALS | PCT/US2014060518 | 2014-10-14 | WO2015057732A8 | 2016-11-03 | HAUBER ROBERT J; BOYDSTON GERALD D; FRAILEY NATHAN; LAMBERET SEVERINE; PATTARKINE GAURAV V; CHERIAN ISAAC K; CENTURIONE SERGIO; GHOSH ANIRBAN |
| A composition and process for manufacture thereof used in hybrid inventive building materials comprising Syngenite (K2Ca(SO4)2.H2O) and Struvite-K (KMgPO4.6H2O). Starting constituents include magnesium oxide (MgO), monopotassium phosphate (MKP) and stucco (calcium sulfate hemihydrate), mixed in predetermined ratios, cause reactions to proceed through multiple phases, which reactions variously are proceeding simultaneously and in parallel. Variables, e.g., water temperature, pH, mixing times and rates, have been found to affect resultant reaction products. Preferred ratios of chemical constituents and manufacturing parameters, including predetermined weight percent and specified ratios of Struvite-K and Syngenite are provided for building products used for specified purposes. Reactions are optimized in stoichiometry and additives to reduce the combined heat of formation to non-destructive levels. Various additives help control and guide reactions. Building products, such as board panels, include the resultant composition. A significant amount of the composition is disposed adjacent a building panel face. | ||||||
| 92 | LOWER HEAT PROCESSED CALCIUM SULPHATES FOR EARLY STRENGTH CEMENTS AND GENERAL USE | PCT/TR2014000037 | 2014-02-18 | WO2014129992A4 | 2015-06-25 | ÖZSÜT MUSTAFA |
| The Invention is related to increasing of early strength and final strengths of cements classified under EN and ASTM as Portland or CEM cements and also related to all clinker employing cements and to any kinds which employ calcium sulphates for set optimization and is for composing of new cements by only assesing new methods for production and is for composing of new cements by only assessing new methods to formation and inclusion of calcium sulphate resources which are used for set optimization.A new calcium sulphate resource is obtained by employing lower heats and this input is arranged to different dehydration levels at which they can be most efficient for the selected use. These different dehydration levels are called intermediate phases of dehydrate or hemihydrates or called as monohydrate.. The Invention clarifies a well defined reactivity power concept which was not defined by the existing scientific basis. As a result, cements which have much higher early strengths than the known could be produced. | ||||||
| 93 | LOWER HEAT PROCESSED CALCIUM SULPHATES FOR EARLY STRENGTH CEMENTS AND GENERAL USE | PCT/TR2014000037 | 2014-02-18 | WO2014129992A9 | 2015-05-21 | ÖZSÜT MUSTAFA |
| The Invention is related to increasing of early strength and final strengths of cements classified under EN and ASTM as Portland or CEM cements and also related to all clinker employing cements and to any kinds which employ calcium sulphates for set optimization and is for composing of new cements by only assesing new methods for production and is for composing of new cements by only assessing new methods to formation and inclusion of calcium sulphate resources which are used for set optimization.A new calcium sulphate resource is obtained by employing lower heats and this input is arranged to different dehydration levels at which they can be most efficient for the selected use. These different dehydration levels are called intermediate phases of dehydrate or hemihydrates or called as monohydrate.. The Invention clarifies a well defined reactivity power concept which was not defined by the existing scientific basis. As a result, cements which have much higher early strengths than the known could be produced. | ||||||
| 94 | PROCESS FOR MANUFACTURING A MONOSULPHONATE ALUMINATE CEMENT AND RESULTING BINDER | PCT/EP2009058813 | 2009-07-10 | WO2010006997A2 | 2010-01-21 | COUTURIER JEAN |
| The present invention relates to a process for manufacturing a hydraulic binder from a compound based on calcium sulphate comprising a firing phase so as to reach a temperature between 220°C and 350°C; then a cooling phase, characterized by the fact that during the firing phase, quicklime is added to the compound based on calcium sulphate so as to obtain the formation of a mixture comprising anhydrite IV. Aluminous and/or siliceous minerals are added to the mixture comprising anhydrite IV, preferably during the cooling phase, so as to reduce the temperature to below 120°C. The invention will in particular find its application in the cement, concrete and plaster industries, and in inerting industrial waste and by-products. | ||||||
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