| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | DIRECTIONAL ELECTROMAGNETIC STEEL SHEET WITH COATING, AND METHOD FOR PRODUCING SAME | US14369476 | 2012-11-12 | US20140377573A1 | 2014-12-25 | Tomoyuki Okubo; Gou Kijima; Makoto Watanabe |
| A directional electromagnetic steel sheet with a coating includes a directional electromagnetic steel sheet; and a coating that is formed on the surface of the directional electromagnetic steel sheet and contains elements P, Si, Cr and O as well as at least one element that is selected from the group consisting of Mg, Al, Ni, Co, Mn, Zn, Fe, Ca and Ba, with 5% by mass or more thereof being composed of a crystalline phase of a phosphate salt. | ||||||
| 122 | METHOD FOR APPLYING A PROTECTIVE LAYER FOR PROTECTING AGAINST IMPACT STRESSES | US14235454 | 2012-07-26 | US20140291326A1 | 2014-10-02 | Juergen Peterseim; Denis Knust; Gerald Beermann |
| A method for applying a protective layer to protect against an impact stress includes mixing a sealing alloy in a powder form with a binder and water to form a pasty compound, applying the pasty compound on a surface to be protected, drying the applied pasty compound, and heating the dried applied pasty compound to a temperature of at least 800° C. | ||||||
| 123 | Soot prevention device for flame curing enameled plate | US85669459 | 1959-12-02 | US3056382A | 1962-10-02 | ERNEST GLASER; TITUS SCHENCK RUHL |
| 124 | Process of preparing fritted foundations for the enameling of metallic articles | US20290738 | 1938-04-19 | US2351811A | 1944-06-20 | KARL FRANK |
| 125 | GROUND COAT ENAMEL COMPOSITION, GROUND COAT ENAMEL LAYER, PRODUCTS CONTAINING SAME AND METHODS FOR PRODUCING SAME | US18022821 | 2021-08-04 | US20230312398A1 | 2023-10-05 | Günter Wilhelm SCHÄFER |
| A ground coat enamel composition for production of an adhesion promoter layer between steel and at least one cover coat enamel for production of an enamel-based coating that is highly corrosion-resistant with respect to mechanical, thermal and chemical effects. The ground coat enamel composition includes boron oxide (B2O3) and alkali metal oxide(s), especially Li2O, Na2O and/or K2O, in percentage proportions by weight: a first main constituent, SiO2 from 35-70%, preferably 40-65%, and, as a second main constituent, from Fe2O3 5-28%, preferably in the range from 7-23% and particularly 8%-15% by weight. Also disclosed is a ground coat enamel layer produced from such a ground coat enamel composition. A highly corrosion-resistant article having such a ground coat enamel layer. A method for producing such a ground coat enamel layer and also a method for producing a highly corrosion-resistant article using such a ground coat enamel composition. | ||||||
| 126 | Heating element including nano-material filler | US15374273 | 2016-12-09 | US10652957B2 | 2020-05-12 | Seyun Kim; Soichiro Mizusaki; Haengdeog Koh; Doyoon Kim; Hajin Kim; Changsoo Lee; Intaek Han |
| A heating element includes a matrix material and a nanomaterial filler, wherein the nanomaterial filler includes at least one of a nano-sheet and a nanorod. | ||||||
| 127 | Heating element including nano-material filler | US15374273 | 2016-12-09 | US10616956B2 | 2020-04-07 | Seyun Kim; Soichiro Mizusaki; Haengdeog Koh; Doyoon Kim; Hajin Kim; Changsoo Lee; Intaek Han |
| A heating element includes a matrix material and a nanomaterial filler, wherein the nanomaterial filler includes at least one of a nano-sheet and a nanorod. | ||||||
| 128 | Method for Heat-Treating a Component Which Consists of a Metal Material and Comprises at Least One Surface Section Coated with a Glaze or Enamel Coating | US16081546 | 2017-03-02 | US20190085466A1 | 2019-03-21 | Bernhard Stauder; Jurij Gontarev |
| A method for heat-treating a component which consists of a metal alloy, in which or on which at least one surface section is coated with a glaze or enamel coating, includes heating the component to a heating temperature which at least equals a minimum quenching temperature, and quenching the component starting from a temperature which at least equals the minimum quenching temperature in order to produce a higher-strength microstructure in the component. The components can be heat-treated such that the glaze or enamel coating is reliably prevented from chipping. The glaze or enamel coating is pre-cooled to a pre-cooling temperature at least on its free surface prior to quenching, said pre-cooling temperature maximally corresponding to the temperature at which the glaze or enamel coating begins to soften, and wherein the cooling rate at which the glaze or enamel coating is cooled is lower than the cooling rate during quenching. | ||||||
| 129 | METAL MEMBER WITH COAT LAYER | US15641327 | 2017-07-05 | US20180016683A1 | 2018-01-18 | Fumiyuki MUTSUDA |
| The present invention provides a coated metal member including a metal base and a coat layer made of an amorphous inorganic material formed on the metal base, the coat layer containing pores and carbon particles. | ||||||
| 130 | Workpiece comprising a laminate to protect against an impact stress | US14235454 | 2012-07-26 | US09752235B2 | 2017-09-05 | Juergen Peterseim; Denis Knust; Gerald Beermann |
| A method for applying a protective layer to protect against an impact stress includes mixing a sealing alloy in a powder form with a binder and water to form a pasty compound, applying the pasty compound on a surface to be protected, drying the applied pasty compound, and heating the dried applied pasty compound to a temperature of at least 800° C. | ||||||
| 131 | Fusion of biocompatible glass/ceramic to metal substrate | US14199293 | 2014-03-06 | US09421303B2 | 2016-08-23 | Orville G. Bailey; Gary Fischman; Petre Bajenaru |
| Applicants have disclosed a process for fusing a biocompatible glass to a metal substrate. In the preferred embodiment, the process comprises: grit blasting a metallic substrate (e.g., titanium) to remove a surface layer of the metal; after blasting, cleaning the abrasion residue off the surface layer; blending a solvent to use as a suspension agent; creating a suspension of biocompatible and bioactive glass-coating powders in the solvent solution; depositing the suspension onto the metallic substrate; drying thoroughly the suspension-coated metallic substrate; inserting the dried, coated substrate into a non-reactive chamber, purging the chamber with an inert gas, such as pure argon; and firing the metallic substrate, inside the furnace, in the inert gas. This process forms a robust fusion between the biocompatible glass and titanium, according to preliminary test results. This process can be used for various medical and dental devices, including implants and onplants. | ||||||
| 132 | Burning bar | US67966233 | 1933-07-10 | US2030707A | 1936-02-11 | MCLEAN LEE R |
| 133 | 一种搪瓷烘干设备用隔热传动结构 | CN202320140771.5 | 2023-02-07 | CN219347222U | 2023-07-14 | 王帮顺; 沈克田; 周琴 |
| 本实用新型提供了一种搪瓷烘干设备用隔热传动结构,属于搪瓷加工技术领域,包括隔绝筒和水冷箱,隔绝筒固定在隔绝筒的顶部,隔绝筒内开设有隔绝风冷腔,隔绝风冷腔内通入流动的空气将内部的热量带走;隔绝风冷腔内竖直穿过输出轴,输出轴的下端伸入到水冷箱内,并且输出轴的下端同步转动连接有传动轴,传动轴的中部同轴固定有第一传动齿轮,输入轴上同轴固定有第二传动齿轮,第二传动齿轮与第一传动齿轮啮合连接;水冷箱内通入冷却液。传动结构将烘干时的热量通过隔绝风冷腔和水冷箱进行冷却,将热量与动力设备(电机)隔绝,避免了热量的传递而使其温度升高,保证动力设备(电机)的工作环境,延长其使用寿命。 | ||||||
| 134 | 一种搪瓷喷涂粉末清理装置 | CN202122418243.5 | 2021-10-08 | CN216192720U | 2022-04-05 | 李仁国 |
| 本实用新型公开了一种搪瓷喷涂粉末清理装置,包括底板,所述底板上端面左侧中部固定连接有L型杆,所述L型杆远离底板的一端右侧滑动连接有滑杆,所述底板上端面右侧前部固定连接有支撑板,所述支撑板后端面上侧固定连接有固定杆,所述固定杆后端面转动连接有第二转动杆,所述滑杆下端面固定连接有升降板,所述滑杆上端面固定连接有滑槽板。本实用新型涉及搪瓷生产领域,该搪瓷喷涂粉末清理装置解决了现有的搪瓷喷涂粉末清理装置不便对搪瓷进行摇晃、清理效率低、不便对粉末进行收集、固定效果差的问题。 | ||||||
| 135 | 一种搪瓷烘干装置 | CN202121760533.1 | 2021-07-30 | CN215864444U | 2022-02-18 | 马洪茹; 李建; 岳庆林; 林阳; 赵毅 |
| 本实用新型属于烘干技术领域,具体涉及一种采用正反交错布局的搪瓷烘干装置,其包括搪瓷釜体、主动轴以及为其提供动力的电机和用于搅拌的桨叶,所述的主动轴上设有反向转动机构,所述的反向转动机构包括安装在主轴上的主动锥形齿轮,以及与主动锥形齿轮啮合连接的从动锥形齿轮,以及与从动锥形齿轮啮合连接的反向锥形齿轮,以及与反向锥形齿轮固定连接的中空的反向轴,反向轴套接在主轴上;主动轴和反向轴上均设有若干个桨叶。本装置设有反向转动机构,通过多个反向转动机构实现多层正反交错搅拌,使物料在釜体内搅拌的更加充分,烘干的效率更高;本装置可以根据物料种类确定反向转动机构的数量,挺高了烘干装置的应用范围,降低了生产成本。 | ||||||
| 136 | 一种内部空间可调节的搪瓷生产用烘干装置 | CN202021610688.2 | 2020-08-06 | CN213147164U | 2021-05-07 | 周干 |
| 本实用新型公开了一种内部空间可调节的搪瓷生产用烘干装置,包括箱体、风扇和加热丝,所述箱体内部的左右两端均固定连接有螺纹杆,所述调节块的外端焊接连接有连接件,所述承载板的内部开设有安装槽,所述防水弹簧的上端固定连接有限位块,所述螺纹杆螺纹连接在蜗轮套的内部,所述箱体的上端开设有出气口,所述箱体的左端焊接连接有加热室,所述加热室的内部中端安装有加热箱,所述加热箱的左端固定连接有第一引导件,所述加热箱的右端固定连接有第二引导件,所述加热室与箱体的前端均铰接连接有密封门。该内部空间可调节的搪瓷生产用烘干装置,内部空间可调节,且容易清洗托盘,并且便于充分对搪瓷制品进行干燥。 | ||||||
| 137 | 一种搪瓷罐一体成型设备 | CN202021978493.3 | 2020-09-11 | CN213142197U | 2021-05-07 | 杨兴华 |
| 本实用新型公开了一种搪瓷罐一体成型设备,包括控温下料室,所述控温下料室中部的上端固定开设有入水口,所述入水口下方的左右两侧固定开设有入料口,所述入料口位于控温下料室的上端,所述控温下料室左右两端的下端固定安装有进料管,所述进料管位于入水口下方的左右两侧。该搪瓷罐一体成型设备,通过将进料管与入料口结合,将水和材料都传输至搅拌混合箱内,在搅拌混合箱安装有微型混搅器,可以将水和材料进行合理的、按照一定比例进行混搅,可以将待塑型的材料进行更加合理的调节工作,通过更有效的混搅后的待塑型材料更加便于塑型工作,更加容易塑型,塑型后的瓷罐更加精致,而装置外侧的外定柱和搅拌混合箱下端的出料口都起到辅助的作用。 | ||||||
| 138 | 美式热水器内胆中桶内壁下部搪瓷釉料自动吹釉装置和系统 | CN202020580334.1 | 2020-04-18 | CN212533132U | 2021-02-12 | 朱海啸; 房传球; 吴海波; 冯亮 |
| 一种美式热水器内胆中桶内壁下部搪瓷釉料自动吹釉装置和系统,其中吹釉装置包括:旋转驱动源,配置成提供旋转力;径向支撑杆,垂直于所述旋转驱动源的输出轴设置;导向件,设在所述径向支撑杆的自由端,用于与美式热水器的内胆中桶下圆配合,使所述导向件沿所述内胆中桶下圆以所述输出轴的轴线为轴心旋转;气嘴,紧邻所述导向件设置,与外接压缩空气源连接,用于将内胆中桶内壁下沿预定高度的搪瓷釉料吹掉。本实用新型具有釉料除净度好,除釉料高度易控,生产效果高和劳动强度低的优点。(ESM)同样的发明创造已同日申请发明专利 | ||||||
| 139 | 一种用于铸造锅胆搪瓷的烘干装置 | CN202021288840.X | 2020-06-28 | CN212505073U | 2021-02-09 | 高国栋; 王源源 |
| 本实用新型公布了一种用于铸造锅胆搪瓷的烘干装置,包括底箱、风机、加热仓、放置板、锅胆本体、竖管和电机,底箱内固接有隔板,隔板将底箱分隔成下方的加热腔和上方的进气腔,加热腔内固接有加热板,风机的出风口通过送风管与加热腔连接,放置板上设有插筒,竖管与底箱连通并通过电机驱动进行转动,竖管上还设有喷头,本实用新型的有益效果是,本装置在使用的时候,锅胆通过插筒进行插接,同时,加热板将风机抽取的外部空气加热并通过竖管和喷头送入到锅胆内,对锅进行烘干,热风烘干可以有效提高烘干的效率,同时,电机驱动竖管和喷头转动,可以使得烘干更加均匀和全面。 | ||||||
| 140 | 一种燃油加热搪瓷管烘道线 | CN201921901334.0 | 2019-11-06 | CN210796628U | 2020-06-19 | 董福根 |
| 本实用新型公开了一种燃油加热搪瓷管烘道线,包括支撑杆,所述支撑杆的上端设置有工作台,所述工作台的上端设置有烘烤室,所述工作台的上端烘烤室的一侧设置有固定机构,所述固定机构包括连接板、固定板、螺纹杆、转动圆盘、限位圆盘,所述工作台的一端设置有转动轴,所述转动轴的一端设置有软质下料板,所述软质下料板的下端设置有调节机构,所述调节机构包括连接杆、固定套管、连接螺丝,所述工作台的后端设置有连接电机,所述工作台的内部设置有传输带。本实用新型所述的一种燃油加热搪瓷管烘道线,可以将搪瓷管固定住,便于搪瓷管的加工,可以便于加工后的搪瓷管的下料,比较方便。 | ||||||
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