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    • 1. 发明申请
    • DOUBLE-SIDED SUPER CAPACITOR AND METHOD FOR MAKING THE SAME
    • 双面超级电容器及其制造方法
    • WO2013100753A1
    • 2013-07-04
    • PCT/MY2012/000163
    • 2012-06-28
    • MIMOS BERHADWITJAKSONO, GunawanBIEN CHIA SHENG, DanielNABIPOOR, Mohsen
    • WITJAKSONO, GunawanBIEN CHIA SHENG, DanielNABIPOOR, Mohsen
    • H01G9/04H01G9/042H01G9/048H01G9/058H01G11/24H01G11/26H01G11/36
    • H01G11/36H01G11/24H01G11/26Y02E60/13Y02T10/7022
    • The present invention provides a nanostructured double-sided super capacitor device dial comprises a substrate, a first metal catalyst layer disposed on top of the substrate, an electric conductive layer disposed and etched on top of the first metal catalyst layer to form a plurality of finger electrodes and contact pads, wherein the plurality of the finger electrodes are configured to be interdigitated, a second metal catalyst layer disposed on the top of the finger electrodes; wherein, when the second metal catalyst layer is disposed, the substrate is etched to expose the first metal catalyst layer underneath of the finger electrodes, so that the top and bottom surfaces of the finger electrodes are exposed, carbon nanotubes (CNTs) extending from the exposed first and second metal catalyst layers of the finger electrodes, electrolyte filled into the finger electrodes and CNTs, and an encapsulating bottom and top encapsulating the interdigitated finger electrodes, CNTs and electrolyte to produce the nanostructured double-sided super capacitor device. The present invention also provides a process of fabricating the nano structured double sided super capacitor.
    • 本发明提供一种纳米结构的双面超级电容器装置拨盘,包括基板,设置在基板顶部的第一金属催化剂层,设置并蚀刻在第一金属催化剂层的顶部上以形成多个手指的导电层 电极和接触垫,其中所述多个指状电极被构造成交叉指向,设置在指状电极的顶部上的第二金属催化剂层; 其中,当设置所述第二金属催化剂层时,蚀刻所述基板以暴露所述指状电极下方的所述第一金属催化剂层,从而暴露所述指状电极的顶表面和底表面,从所述第二金属催化剂层延伸的碳纳米管 手指电极暴露的第一和第二金属催化剂层,填充到指状电极和CNT中的电解质,以及封装交错指状电极的封装底部和顶部,CNT和电解质以产生纳米结构的双面超级电容器器件。 本发明还提供一种制造纳米结构双面超级电容器的方法。
    • 2. 发明申请
    • A HEAT SINK AND A METHOD OF ENHANCING HEAT DISSIPATION THEREOF
    • 一种散热器及其散热方法
    • WO2012002796A1
    • 2012-01-05
    • PCT/MY2011/000051
    • 2011-05-23
    • MIMOS BERHADABDULLAH, Muhammad, SyargawiWITJAKSONO, Gunawan
    • ABDULLAH, Muhammad, SyargawiWITJAKSONO, Gunawan
    • H01L23/373G02B6/43H05K1/00
    • G02B6/4201G02B6/4269H05K1/0206H05K1/0207H05K2201/10121
    • A heat sink in an electronic circuit board (PCB) comprising a plurality of PCB layers (10) wherein a first PCB layer (100) is mountable with a plurality of electronic components (140) is provided, characterized in that, the heat sink includes at least one optical component (102) mountable on a first heat spreader (103), by a thermal cohesive means (104), wherein the first heat spreader (103) is attachable to the first PCB layer (100), a second PCB layer (110) is thermally conductible to the first PCB layer (100) by at least one thermal via (112), a third PCB layer (120) is thermally conductible to the second PCB layer (110) by the at least one thermal via (112), a bottom PCB layer (130) is thermally conductible to the third PCB layer (120) by the at least one thermal via (112), such that heat is conductible through the plurality of PCB layers (10) for enhanced thermal dissipation from the plurality of electronic components (140).
    • 提供了一种包括多个PCB层(10)的电子电路板(PCB)中的散热器,其中第一PCB层(100)可安装有多个电子部件(140),其特征在于,所述散热器包括 至少一个光学组件(102),可通过热粘合装置(104)安装在第一散热器(103)上,其中第一散热器(103)可附接到第一PCB层(100),第二PCB层 (110)通过至少一个热通孔(112)可导热到第一PCB层(100),第三PCB层(120)可通过至少一个热通孔(120)导热到第二PCB层(110) 112),通过所述至少一个热通孔(112),底部PCB层(130)可热传导到所述第三PCB层(120),使得热量可传导通过所述多个PCB层(10)以增强热耗散 来自所述多个电子部件(140)。
    • 3. 发明申请
    • A METHOD OF FABRICATING AN ENERGY HARVESTING MEANS AND A DEVICE THEREOF
    • 一种制造能量采集装置的方法及其装置
    • WO2013009164A1
    • 2013-01-17
    • PCT/MY2012/000146
    • 2012-06-26
    • MIMOS BERHADUZ., ZAMAN, Mukter A.S.MWITJAKSONO, GunawanOTHMAN, Masuri
    • UZ., ZAMAN, Mukter A.S.MWITJAKSONO, GunawanOTHMAN, Masuri
    • H01M6/40H01M8/10
    • H01M8/1097H01M6/40H01M6/42H01M6/46
    • A method of fabricating an energy harvesting means, the method includes the steps of depositing a metal conducting element (200) on a substrate (100), patterning the metal conducting element (200) such that a layer of metal with a plurality of grooves (220) are produced, depositing a solid polymer electrolyte (SPE) layer (300) on the metal conducting element (200), depositing a layer of air-electrode (400) on the SPE layer (300), patterning the layer of air-electrode (400) and the SPE layer (300) to produce grooves (420) connecting the metal conducting element (200), growing a conductive layer (500) between the metal conducting element (200), the SPE layer (300) and the layer of air-electrode (400), patterning the conductive layer (500) and the layer of air-electrode (400) to connect to the SPE layer (300) by a plurality of grooves (520) and forming a non-conductive layer (600) between the layer of air-electrode (400) and the plurality of layers, wherein the method includes connecting terminals and encapsulation of the energy harvesting means.
    • 一种制造能量收集装置的方法,所述方法包括以下步骤:将金属导电元件(200)沉积在基底(100)上,使金属导电元件(200)图案化,使得具有多个凹槽 220),在所述金属导电元件(200)上沉积固体聚合物电解质(300),在所述SPE层(300)上沉积空气电极层(400),将所述空气 - 电极(400)和SPE层(300),以产生连接金属导电元件(200)的凹槽(420),在金属导电元件(200),SPE层(300)和 空气电极层(400),图案化导电层(500)和空气电极层(400),以通过多个沟槽(520)连接到SPE层(300),并形成非导电层 (400)和所述多个层之间的所述方法(600),其中所述方法包括连接 终端和能量收集装置的封装。
    • 5. 发明申请
    • A SIX QUANTUM STATE PRODUCING ENCODER SYSTEM AND A METHOD OF PRODUCING THEREOF
    • 生产编码器系统的六个量子态及其生产方法
    • WO2012018246A1
    • 2012-02-09
    • PCT/MY2010/000293
    • 2010-11-25
    • MIMOS BERHADABDULLAH, Muhammad, SyargawiWITJAKSONO, GunawanMOKHTAR, Mohd, Hadri, Hafiz
    • ABDULLAH, Muhammad, SyargawiWITJAKSONO, GunawanMOKHTAR, Mohd, Hadri, Hafiz
    • H04B10/12H04L9/08
    • H04B10/70H04L9/0855
    • A six quantum state producing encoder system (100) for deterministic six states protocol of Quantum Key Distribution is provided, the system (100) includes at least three laser diodes (610, 620, 630), at least three current drivers (510, 520, 530) wherein each of the at least three laser diodes (610, 620, 630) are at different polarization states and each laser diode is drivable by each current driver, at least three switches (410, 420, 430) connectable to the at least three current drivers (510, 520, 530), at least one pulse width modulator (PWM) generator (220) connectable to the at least three switches (410, 420, 430) and a controller wherein the at least three switches (410, 420, 430) are triggerable by the controller, wherein the system (100) is configurable to select a pair of different laser diodes with new polarization states for every two consecutive period, wherein two different laser diodes are interchangeably triggered for every two consecutive periods for automatic production of six quantum states.
    • 提供了一种用于量子密钥分发的确定性六态协议的六量子态产生编码器系统(100),系统(100)包括至少三个激光二极管(610,620,630),至少三个电流驱动器 ,530),其中所述至少三个激光二极管(610,620,630)中的每一个处于不同的偏振状态,并且每个激光二极管可由每个电流驱动器驱动,至少三个可连接到所述激活二极管的开关(410,420,430) 至少三个电流驱动器(510,520,530),可连接到所述至少三个开关(410,420,430)的至少一个脉宽调制器(PWM)发生器(220)和控制器,其中所述至少三个开关 ,420,430)可由所述控制器触发,其中所述系统(100)可配置为每两个连续周期选择具有新偏振态的一对不同的激光二极管,其中两个不同的激光二极管可互换触发每两个连续周期 用于自动产品 六个量子态的离子。
    • 8. 发明申请
    • LUMINESCENCE BASED WATER QUALITY SENSORS SYSTEM
    • 基于发光的水质传感器系统
    • WO2015080549A1
    • 2015-06-04
    • PCT/MY2014/000117
    • 2014-05-26
    • MIMOS BERHAD
    • ABDULLAH, Muhammad Syargawi BinMOHD ZAIN Mohd Norzaliman BinABDUL KHIR Mohd Fared BinWITJAKSONO, GunawanSAHARUDIN, Suhairi Bin
    • G01N21/64G01N21/77G01J3/44
    • G01J3/4406G01N21/6408
    • A luminescence based water quality sensor system (10) comprises a dual sensor material (300) having at least one layer of two indicator sensor dyes (301,302) that display two largely different decay times in a single hydrogel matrix, in which each indicator sensor dyes measures a specific analyte relating to water quality, a light source (100) which provides photon source to the dual sensor material (300), an excitation source (200) which includes a polarization controller (201) to modulate and polarize the light source (100), and a detector unit (400) having a spectral filter (401) to filter the emission wavelength before detecting by a photodetector (402). The changes of the analyte to be measured quenches the luminescence emission of a sensor dye. The sensor system (10) allows for a real-time and simultaneous calculation of the concentration of at least two analytes to be measured.
    • 基于发光的水质传感器系统(10)包括双传感器材料(300),其具有至少一层两个指示剂传感器染料(301,302),其在单个水凝胶基质中显示两个大不相同的衰变时间,其中每个指示剂传感器染料 测量与水质相关的特定分析物,向双重传感器材料(300)提供光子源的光源(100);激励源(200),其包括调节和偏振光源的偏振控制器(201) 100),以及具有光谱滤波器(401)的检测器单元(400),用于在由光电检测器(402)检测之前对发射波长进行滤波。 待测分析物的变化会猝灭传感器染料的发光。 传感器系统(10)允许对要测量的至少两种待分析物的浓度进行实时和同时的计算。
    • 9. 发明申请
    • COMPOUND LENS FOR SOLAR HEAT COLLECTION
    • 化合物镜片用于太阳能热收集
    • WO2014014338A1
    • 2014-01-23
    • PCT/MY2013/000127
    • 2013-07-10
    • MIMOS BERHAD
    • ABD AZIZ, Aiman SajidahZAMAN, A.S.M Mukter UzABDUL RASHID, NorazahWITJAKSONO, Gunawan
    • F24J2/08G02B19/00
    • G02B19/0042F24S23/30G02B19/0014Y02E10/40
    • A refraction method and a compound lens is disclosed for concentrating solar beam in a non-imaging manner for its heat to be harvested and utilized, for example, for generating electricity with thermo-electric or thermocouple circuit when its hot junction is heated. Solar beam (SI), which may be collected over a wide span of the sun's movement without need for tracking, is first refracted with a first positive refractory element which may preferably be an asperical biconvex lens (11). The exiting, i.e. second solar beam (S2), at a still convergent angle is then refracted by a second negative refractory element which may preferably be a biconcave lens (12). The exiting, i.e. third solar beam (S3), converges upon a third positive refractory element, preferably another aspherical biconvex lens (13), which concentrates the exiting solar beam (S4) onto the predetermined heat collection surface area (120). The sum of all the curvature surfaces of the compound lens times the indices of refraction is about zero such that the field of focus is flat. Preferably, the sum of refractive powers of the first and third aspherical biconvex lenses is substantially counter-balanced by the refractive power of the second biconcave lens placed thereinbetween said first and third lenses.
    • 公开了一种折射方法和复合透镜,用于以非成像方式集中太阳能射束以获得和利用其热量,例如,当其热连接被加热时用于用热电或热电偶电路发电。 首先用可能优选为无色双凸透镜(11)的第一正耐火材料折射可在太阳运动的宽跨度上收集的太阳能束(SI),而不需要跟踪。 然后,退出的即第二太阳能光束(S2)以仍然会聚的角度被第二负的难熔元件折射,第二负的耐火元件可以优选地是双凹透镜(12)。 离开的即第三太阳能光束(S3)会聚在第三阳极耐火元件上,优选另一个非球面双凸透镜(13),其将出射的太阳能束(S4)集中到预定的集热表面区域(120)上。 复合透镜的所有曲率面的总和乘以折射率约为零,使得焦点的平面。 优选地,第一和第三非球面双凸透镜的折射率的总和通过其中放置在所述第一和第三透镜之间的第二双凹透镜的屈光力实质上反平衡。
    • 10. 发明申请
    • PROCESS OF TEXTURING SILICON SURFACE FOR OPTIMAL SUNLIGHT CAPTURE IN SOLAR CELLS
    • 太阳能电池中最佳太阳能捕获硅胶表面的工艺
    • WO2015088320A1
    • 2015-06-18
    • PCT/MY2014/000170
    • 2014-06-10
    • MIMOS BERHAD
    • WITJAKSONO, GunawanZAMAN, A. S. M. Mukter UzABDUL RAZAK, Nurul Huda
    • H01L31/0236H01L31/0747
    • H01L31/18
    • A process of treating a silicon substrate surface for optimizing sunlight capture in the fabrication of solar cells is disclosed. Each of the two sides of the silicon substrate is textured with a laser source to roughen its surface by fabricating nanoscale structures thereon. Surface texturing may be conducted on both sides of a crystalline silicon wafer by flipping over to repeat our process on the other side such that sunhght reflectivity is minimized and photon trapping is maximized. The process may be conducted in room temperature and vacuum in a dry-etch processing environment. The substrate may undergo translation in the X- Y axes for control of the substrate's movement to achieve the requisite texturing by the laser beam of a pulse laser of Nd-YAG source in 533 nm and 1024 nm wavelengths at > 75 joules/pulse with translation speed of
    • 公开了一种在制造太阳能电池中处理硅衬底表面以优化阳光捕获的方法。 通过在其上制造纳米尺度结构,用激光源对硅衬底的两侧进行纹理化以使其表面粗糙化。 表面纹理可以在晶体硅晶片的两面上翻转,在另一侧重复我们的工艺,使得sunhght反射率最小化并且光子俘获被最大化。 该方法可以在干蚀刻加工环境中在室温和真空下进行。 衬底可以在X-Y轴上进行平移以控制衬底的运动,以通过Nd-YAG源的脉冲激光束在533nm和1024nm波长的激光束以> 75焦耳/脉冲达到必要的纹理,并且具有平移 速度<0.5mm /秒。 我们的工艺适用于包括异质结构,特别是具有本征薄层(HIT)结构,特别是在晶体硅(c-Si)(p型))衬底上的太阳能电池,其可以包括暴露于纳秒级到毫微微 干式薄膜太阳能电池晶圆上的第二范围脉冲激光。