• 
<tr id="yyy80"></tr>
    • <sup id="yyy80"></sup>
  • 

    <tfoot id="yyy80"><noscript id="yyy80"></noscript></tfoot>
  • 
99热精品在线国产_美女午夜性视频免费_国产精品国产高清国产av_av欧美777_自拍偷自拍亚洲精品老妇_亚洲熟女精品中文字幕_www日本黄色视频网_国产精品野战在线观看 
?
    
	
    
		
		
		
	
    

    

    
    
    
    
    
        
    
            
    碳納米管功能層在等離子體顯示中的應(yīng)用研究
    
                
    2016-04-05 10:29:44王小菊成都信息工程大學(xué)光電技術(shù)學(xué)院成都605電子科技大學(xué)光電信息學(xué)院成都60054
    
                
    關(guān)鍵詞:延遲時(shí)間信息工程保護(hù)層
    
                    
    鄧 江,王小菊(. 成都信息工程大學(xué)光電技術(shù)學(xué)院 成都 605;. 電子科技大學(xué)光電信息學(xué)院 成都 60054)
    ?
    碳納米管功能層在等離子體顯示中的應(yīng)用研究
    鄧 江1,王小菊2
    (1. 成都信息工程大學(xué)光電技術(shù)學(xué)院 成都 610225;2. 電子科技大學(xué)光電信息學(xué)院 成都 610054)
    【摘要】采用噴涂法在等離子體顯示面板(AC PDP)的MgO保護(hù)層上噴涂碳納米管(CNTs)作為功能層,研究該復(fù)合型保護(hù)層的可見(jiàn)光透過(guò)率和放電性能。結(jié)果表明,CNTs/MgO保護(hù)層的可見(jiàn)光透過(guò)率超過(guò)80%。且與純MgO保護(hù)層相比, CNTs/MgO保護(hù)層單元的著火電壓和放電延遲時(shí)間明顯降低。在100 torr、10% Xe+Ne的放電條件下,CNTs/MgO保護(hù)層的著火電壓和放電延遲時(shí)間分別為263.5 V和270 ns,與純MgO保護(hù)層相比,分別降低了15%和26%。因此,CNTs/MgO保護(hù)層在AC PDP中具有潛在的應(yīng)用前景。
    關(guān) 鍵 詞碳納米管; 放電延遲時(shí)間; 著火電壓; 保護(hù)層; 透過(guò)率
    Compared with other display devices, plasma display panels (AC PDPs) have several advantages[1-2], such as high contrast, high luminance, and large size. Generally, MgO film is used as the protective layer of AC PDP. It plays an important role in influencing the driving voltages of AC PDP and protecting the electrodes and dielectric layer from the bombardment of ions, electrons, photons, and metastable atoms, which exist in AC PDP during the discharge operation. However, at present, the discharge voltages (the firing and sustain voltages) of AC PDP with a conventional MgO protective layer are still considered to be too high, which results in high electrical power consumption and urges people to look for new protective materials.
    In the past years, a doped MgO layer[3-5], a double protective layer[6-8], and new materials instead of MgO protective layer[9-10], have been emerged in many papers, mainly in order to improve the luminous efficiency and reduce power consumption. According to the discharge mechanism of AC PDP, priming electrons are required to ignite a discharge. Recently, our group has studied the application of hexaboride lanthanum (LaB6) in AC PDP. Because of the low work function of LaB6, it was easy to generate priming electrons, and lower firing voltage and shorter discharge delay time were obtained accordingly[11-12].
    In this work, carbon nanotubes (CNTs) were coated on a conventional MgO protective film by aspray coating method as a functional layer. CNT is an excellent field emission material and it has attracted considerable attention due to its excellent electronic and structural properties. Among the various applications, Report on the extraordinary high electron-induced SEE yields for MgO/CNTs suggested the possibility of its application in AC PDP, in which MgO film was deposited on CNTs surface[13]. In this work, we studied the possible application of the CNTs/MgO protective layer to AC PDP by fabricating a prototype of AC PDP and testing the discharge characteristics. This structure is different from that in Ref. [13] which CNTs was coated on MgO protective film to act as a functional layer.
    1 Experiments
    In our experiment, the substrates were provided by Changhong Display Device Co. Ltd., Mianyang China, which included indium thin oxide (ITO) layer, transparent dielectric layer, and an MgO protective layer. The preparation process of spray coated CNTs was as follows. First, the MWNTs (0.1 g), ethyl cellulose (80 mL), and acetone (120 mL) were mixed and ultrasonic vibrated for 24 h to form a type of solution. Next, the solution was coated on the substrate by a spray gun and dried at 120 ℃ in air for 10 min. To observe the visible light transmittance and discharge properties of fabricated CNTs/MgO protective layer, the products were characterized and analyzed by an ultraviolet-visible spectrophotometer and an AC PDP discharge test system, respectively.
    Fig. 1 shows the structure of the AC PDP test cell used in this experiment. Dielectric layers with the thickness of 21 μm and barrier ribs with the height of 120 μm were prepared by the screen-printing method. The transparent indium tin oxide (ITO) layer with the thickness of 130 nm was fabricated by the magnetron sputtering method and patterned by the lithography process. The MgO protective layer with the thickness of 800 nm was formed on the dielectric layer by electron beam evaporation and then a very small amount of CNTs was coated on the MgO film as a functional layer. The coplanar gap between the common electrode and the scan electrode was 80 μm, and the width of the barrier was 50 μm. The discharge gas consisted of Ne and Xe at 20~100 torr.
    Fig. 1 Schematic diagram of the AC PDP prototype used in this experiment.
    2 Results and discussions
    Fig. 2 shows the visible light transmittance of CNTs/MgO protective layer, using a conventional MgO protective layer as a reference. It indicates that, the relative transmittance of CNTs/MgO protective layer is more than 80 % in the 400 nm to 800 nm wavelength range. Especially, in the 500 nm to 550 nm wavelength range, the transmittance is high up to 90%.
    Fig. 2 Visible light transmittances of CNTs/MgO protective layer using a conventional MgO protective layer as a reference.
    Fig. 3 compares the firing voltages of the test panels with a CNTs/MgO protective layer and a conventional MgO protective layer in 5 % and 10 % Xe-Ne, respectively. It is found that no matter how high the pressure is, the discharge voltage of the test panel with CNTs/MgO is lower than that with a conventional MgO layer. Especially, with 100 torr 10% Xe-Ne applied to the testing system, the firing voltage of the AC PDP test cell with CNTs/MgO protective layer is 263.5 V, which is 15 % lower than that with a conventional MgO protective layer (308.5 V). According to Paschen’s law, the firing voltage (Vf) is dependent on the content of gas mixture, the gas pressure, and the emission characteristics of theprotective layer. It is defined by the following equation.
    where A and B are constants determined by the properties of the gas, P is the gas pressure, d is the distance between electrodes, andγis the secondary electron emission yield. We can conclude that the CNTs/MgO structure has higher γ than a conventional MgO layer. One of the possible reasons for the SEE enhancement may be ascribed to the geometrical feature of CNTs, i.e., high aspect ratio, and small tip radius at the apex. In addition, according to the potential theory, the γ value is proportional towhere Eiis the ionization energy and φ is the work function of the film. We can assume that CNTs/MgO has a smaller work function than conventional MgO. The reason of the decrease in the work function is not proven, so further investigation is needed.
    Fig. 3 Firing voltages of AC PDP test cells with a CNTs/MgO protective layer and a conventional MgO protective layer versus gas pressure.
    Fig. 4 Discharge delay time of AC PDP test cells with a CNTs/MgO protective layer and a conventional MgOprotective layer versus gas pressure.
    Fig. 4 shows the discharge delay time of the test panels with a CNTs/MgO protective layer and a conventional MgO protective layer, respectively. It is found that the test cell with a CNTs/MgO protective layer always presents much shorter discharge delay time than that with a pure MgO protective layer. The reciprocal of the statistical delay is expressed as
    where Yeis the generation rate of priming electrons and0P is the probability of a discharge being caused by one initial priming electron[14]. Because0P is constant for a particular cell structure and electric field, tsis determined by the priming electron emission rate. We can assume that the priming electrons are emitted by the field emission of CNTs when the measuring voltages are applied. Before the measuring voltage is applied, CNTs near the anode have a negative charge wall charge induced by the previous discharges because the CNTs are in contact with the insulator. When the measuring voltage is applied, the CNTs act as cathodes, resulting in fieldelectron emission. Then, tsof CNTs/MgO protective layer is reduced. As shown in Fig. 4b, with 100 torr 10% Xe-Ne pressure, the discharge delay time for the PDP cell with a CNTs/MgO protective layer reaches 270 ns, which is 26 % lower than a conventional MgO protective layer (365 ns).
    3 Conclusions
    In conclusion, the transmittance and discharge properties of a CNTs/MgO protective layer used in AC PDP have been investigated. Both the firing voltages and discharge delay time of the test cell decrease are attributed to the addition of CNTs functional layer. The electron emission from CNTs can be explained by the field emission, which is different from the mechanism of electron emission from the MgO film and is beneficial to improve the discharge properties of AC PDP.
    參 考 文 獻(xiàn)
    [1] CHEN Y X, LI Q, HU K, et al. Wall-voltage stability in AC-PDP dielectric barrier discharges[J]. IEEE Transactions on Plasma Science, 2013, 41(1): 159-164.
    [2] KIM D M, SHIN B J, TAE H S, et al. Improvement of luminous efficacy using short sustain pulse width and long off-time between sustain pulses in AC plasma display panel[J]. IEEE Transactions on Plasma Science, 2013, 41(4): 887-890.
    [3] AHNS Il, LEE S E, RYU S H, et al. A study on the secondary electron emission from Na-ion-doped MgO films in relation to the discharge characteristics of plasma display panels[J]. Thin Solid Films, 2009, 517: 1706-1709.
    [4] KIM J K. Modification of a driving waveform in an AC plasma display panel with Sc-doped MgO protecting layer[J]. IEEE Transactions on Electron Devices, 2013, 60(8): 2556-2560.
    [5] KIM W H, CHO K H, CHOI K C, et al. Influence of gold nanoparticles on the characteristics of plasma display panels[J]. IEEE Transactions on Electron Devices, 2010, 57(10): 2644-2650.
    [6] LEE T H, CHEONG H W, KWON O, et al. Application of MgCaO cathode layer to plasma display panel for high luminous efficacy[J]. IEEE Transactions on Electron Devices, 2013, 60(1): 301-304.
    [7] PARK C S, TAE H S, JUNG E Y. Influence of Al2O3reflective layer under phosphor layer on luminance and luminous efficiency characteristics in alternating-current plasma display panel[J]. Thin Solid Films, 2013, 547: 43-46.
    [8] JUNG H Y, LEE T H, KWON O, et al. Realization of high luminous efficacy at low voltages in the plasma display panel with SrO-MgO double layer[J]. IEEE Electron Device letters, 2010, 31(7): 686-688.
    [9] YASUSHI M, HIDEOMI M, HIROSHI M. A study of the secondary electron yield γ of insulator cathodes for plasma display panels[J]. IEEE Transactions on Electron Devices, 2001, 48(8): 1568-1574.
    [10] MOTOYAMA Y, MURAKAMI Y, SEKI M, et al. SrCaO protective layer for high-efficiency PDPs[J]. IEEE Transactions on Electron Devices, 2007, 54(6): 1308-1313.
    [11] DENG J, ZENG B Q, WANG X J, et al. Improvement of discharge properties by printing LaB6films on MgO protective layers in plasma display panel[J]. IEEE Electron Device Letter, 2013, 34(8): 1026-1028.
    [12] WANG X J, DENG J, LIU Z Y, et al. Discharge characteristics of LaB6protecting thin films in ac plasma display panel[J]. Chinese Science Bulletin, 2012, 57: 2544-2546.
    [13] LEE W T, IM S J, HAN J G, et al. MgO/carbon nanotubes protective layer in ac-plasma display panels[J]. Japanese Journal of Applied Physics, 2002, 41: 6550-6552.
    [14] OKADA T, YOSHIOKA T. Application of carbon nanotubes as a source of priming electrons in ac plasma display panels[J]. Applied Physics Letter, 2008, 93: 171501.
    編 輯 黃 莘
    作者簡(jiǎn)介:鄧江(1978 ? ),男,博士,主要從事氣體放電、顯示方面的研究.
    收稿日期:2014 ? 03 ? 11;修回日期: 2015 ? 05 ? 04
    中圖分類(lèi)號(hào)O461.2
    文獻(xiàn)標(biāo)志碼A
    doi:10.3969/j.issn.1001-0548.2016.01.026
    Received date:2014 ? 03 ? 11;Revised date:2015 ? 05 ? 04
    Biography:DENG Jiang was born in 1978, and his research interests include gas discharge and display.
    

    
                        
    猜你喜歡
    
                        
    延遲時(shí)間信息工程保護(hù)層
    
                        
    江蘇高速公路信息工程有限公司
    二氧化碳對(duì)乙烷燃燒著火延遲時(shí)間的影響
    煤氣與熱力(2021年3期)2021-06-09 06:16:22
    LTE 系統(tǒng)下行鏈路FDRX 節(jié)能機(jī)制研究
    基于分層COX模型的跟馳反應(yīng)延遲時(shí)間生存分析
    信息工程技術(shù)的應(yīng)用與發(fā)展
    計(jì)算機(jī)網(wǎng)絡(luò)在電子信息工程中的應(yīng)用
    尋找空氣保護(hù)層
    延遲時(shí)間對(duì)氣輔注射成型氣體穿透行為影響的數(shù)值模擬和實(shí)驗(yàn)研究
    近距離煤層群上保護(hù)層保護(hù)范圍的數(shù)值模擬
    保護(hù)層開(kāi)采工作面過(guò)地質(zhì)異常區(qū)期間瓦斯綜合治理技術(shù)
    
                    
    
            
    
        
    
        
        
    
    
    

    










国产精品香港三级国产av潘金莲
|
日韩一卡2卡3卡4卡2021年|
亚洲av国产av综合av卡|
人体艺术视频欧美日本|
黑丝袜美女国产一区|
大陆偷拍与自拍|
天天操日日干夜夜撸|
日产精品乱码卡一卡2卡三|
成人国产麻豆网|
性少妇av在线|
又粗又硬又长又爽又黄的视频|
搡女人真爽免费视频火全软件|
亚洲伊人久久精品综合|
日韩三级伦理在线观看|
青青草视频在线视频观看|
久久影院123|
久久ye,这里只有精品|
丰满乱子伦码专区|
www.熟女人妻精品国产|
91久久精品国产一区二区三区|
久久久久久久久免费视频了|
黄色怎么调成土黄色|
看免费av毛片|
国产成人a∨麻豆精品|
一本大道久久a久久精品|
日本欧美国产在线视频|
久久久久精品性色|
日韩一区二区三区影片|
亚洲精品在线美女|
亚洲国产色片|
黄网站色视频无遮挡免费观看|
少妇 在线观看|
久久久久网色|
老司机亚洲免费影院|
欧美精品亚洲一区二区|
日韩一区二区三区影片|
久久久久久人人人人人|
久久久久久人妻|
久久精品国产鲁丝片午夜精品|
91成人精品电影|
久久国产精品男人的天堂亚洲|
亚洲视频免费观看视频|
超色免费av|
免费久久久久久久精品成人欧美视频|
美女国产高潮福利片在线看|
videos熟女内射|
国产精品.久久久|
成人黄色视频免费在线看|
欧美精品av麻豆av|
9热在线视频观看99|
婷婷色av中文字幕|
999久久久国产精品视频|
欧美成人精品欧美一级黄|
亚洲图色成人|
涩涩av久久男人的天堂|
欧美成人精品欧美一级黄|
欧美亚洲日本最大视频资源|
老熟女久久久|
男人添女人高潮全过程视频|
99国产精品免费福利视频|
黄色一级大片看看|
黑丝袜美女国产一区|
电影成人av|
国产精品无大码|
国产精品偷伦视频观看了|
免费观看a级毛片全部|
又大又黄又爽视频免费|
18禁裸乳无遮挡动漫免费视频|
欧美中文综合在线视频|
两个人看的免费小视频|
日日爽夜夜爽网站|
国产精品久久久久久久久免|
女性生殖器流出的白浆|
一本色道久久久久久精品综合|
亚洲中文av在线|
永久免费av网站大全|
成人国语在线视频|
a级毛片黄视频|
一级爰片在线观看|
男女啪啪激烈高潮av片|
一区二区三区精品91|
丝袜人妻中文字幕|
中文字幕亚洲精品专区|
久久久国产欧美日韩av|
国产一区有黄有色的免费视频|
自线自在国产av|
国产精品香港三级国产av潘金莲
|
这个男人来自地球电影免费观看
|
国产国语露脸激情在线看|
成人国产av品久久久|
日韩免费高清中文字幕av|
欧美 亚洲 国产 日韩一|
水蜜桃什么品种好|
啦啦啦啦在线视频资源|
久久久久久久大尺度免费视频|
国产深夜福利视频在线观看|
亚洲国产看品久久|
人人妻人人爽人人添夜夜欢视频|
国产精品.久久久|
午夜福利网站1000一区二区三区|
只有这里有精品99|
菩萨蛮人人尽说江南好唐韦庄|
中国国产av一级|
少妇熟女欧美另类|
捣出白浆h1v1|
精品久久久久久电影网|
亚洲欧美中文字幕日韩二区|
免费在线观看完整版高清|
免费高清在线观看视频在线观看|
制服人妻中文乱码|
韩国精品一区二区三区|
看十八女毛片水多多多|
亚洲成国产人片在线观看|
亚洲成人手机|
久久国产精品男人的天堂亚洲|
成人毛片60女人毛片免费|
av网站在线播放免费|
黄色视频在线播放观看不卡|
尾随美女入室|
人人妻人人澡人人看|
国产1区2区3区精品|
欧美成人午夜免费资源|
亚洲第一区二区三区不卡|
高清av免费在线|
下体分泌物呈黄色|
免费看不卡的av|
久久精品亚洲av国产电影网|
欧美日韩视频高清一区二区三区二|
亚洲成人一二三区av|
国产一区二区激情短视频
|
国产成人91sexporn|
国产男人的电影天堂91|
综合色丁香网|
中文乱码字字幕精品一区二区三区|
黄色 视频免费看|
国产又爽黄色视频|
精品少妇黑人巨大在线播放|
男女免费视频国产|
最新中文字幕久久久久|
√禁漫天堂资源中文www|
91精品伊人久久大香线蕉|
麻豆乱淫一区二区|
如何舔出高潮|
一个人免费看片子|
国产精品国产av在线观看|
亚洲中文av在线|
免费观看av网站的网址|
制服诱惑二区|
午夜激情久久久久久久|
午夜免费鲁丝|
videossex国产|
免费看av在线观看网站|
美女午夜性视频免费|
欧美精品人与动牲交sv欧美|
桃花免费在线播放|
电影成人av|
99热网站在线观看|
色视频在线一区二区三区|
伊人久久大香线蕉亚洲五|
97在线人人人人妻|
美女大奶头黄色视频|
久久热在线av|
一个人免费看片子|
日本av免费视频播放|
亚洲国产欧美网|
精品国产一区二区三区四区第35|
亚洲色图 男人天堂 中文字幕|
男男h啪啪无遮挡|
国产xxxxx性猛交|
亚洲精品视频女|
午夜免费鲁丝|
一个人免费看片子|
国产 一区精品|
亚洲成人手机|
a级片在线免费高清观看视频|
免费观看a级毛片全部|
精品久久久精品久久久|
深夜精品福利|
日韩精品有码人妻一区|
亚洲欧美中文字幕日韩二区|
色94色欧美一区二区|
午夜激情久久久久久久|
亚洲精品国产av蜜桃|
国产精品av久久久久免费|
国产亚洲午夜精品一区二区久久|
国产欧美日韩一区二区三区在线|
天天躁夜夜躁狠狠久久av|
综合色丁香网|
国产精品一区二区在线不卡|
天天躁夜夜躁狠狠躁躁|
成年美女黄网站色视频大全免费|
欧美日韩视频高清一区二区三区二|
国产乱人偷精品视频|
母亲3免费完整高清在线观看
|
av在线app专区|
满18在线观看网站|
国产欧美亚洲国产|
午夜福利网站1000一区二区三区|
爱豆传媒免费全集在线观看|
国产成人欧美|
中文天堂在线官网|
美国免费a级毛片|
熟女av电影|
国产成人免费观看mmmm|
国产日韩欧美视频二区|
香蕉丝袜av|
久久ye,这里只有精品|
亚洲av在线观看美女高潮|
亚洲av欧美aⅴ国产|
啦啦啦中文免费视频观看日本|
国产日韩欧美亚洲二区|
成人手机av|
一级毛片我不卡|
久久久精品免费免费高清|
一区在线观看完整版|
2021少妇久久久久久久久久久|
1024香蕉在线观看|
国产精品亚洲av一区麻豆
|
av视频免费观看在线观看|
日韩伦理黄色片|
色婷婷久久久亚洲欧美|
90打野战视频偷拍视频|
天堂8中文在线网|
亚洲少妇的诱惑av|
亚洲美女黄色视频免费看|
夜夜骑夜夜射夜夜干|
国产成人午夜福利电影在线观看|
国产一区亚洲一区在线观看|
日韩制服丝袜自拍偷拍|
如日韩欧美国产精品一区二区三区|
久久精品国产综合久久久|
日韩欧美一区视频在线观看|
精品国产乱码久久久久久小说|
五月天丁香电影|
日韩一区二区视频免费看|
国产av码专区亚洲av|
亚洲国产毛片av蜜桃av|
人妻 亚洲 视频|
亚洲精品aⅴ在线观看|
亚洲综合色网址|
亚洲四区av|
日韩制服丝袜自拍偷拍|
videosex国产|
免费在线观看黄色视频的|
亚洲av电影在线观看一区二区三区|
曰老女人黄片|
tube8黄色片|
一级毛片黄色毛片免费观看视频|
av又黄又爽大尺度在线免费看|
高清欧美精品videossex|
高清在线视频一区二区三区|
五月开心婷婷网|
成人黄色视频免费在线看|
黑人欧美特级aaaaaa片|
韩国av在线不卡|
80岁老熟妇乱子伦牲交|
少妇被粗大猛烈的视频|
一级a爱视频在线免费观看|
videosex国产|
日本爱情动作片www.在线观看|
少妇精品久久久久久久|
国产欧美日韩综合在线一区二区|
一边摸一边做爽爽视频免费|
国产成人精品无人区|
美女福利国产在线|
久久精品国产亚洲av涩爱|
2018国产大陆天天弄谢|
国产日韩欧美亚洲二区|
精品一区二区三区四区五区乱码
|
一本—道久久a久久精品蜜桃钙片|
国产精品国产三级国产专区5o|
香蕉丝袜av|
看免费av毛片|
国产不卡av网站在线观看|
av片东京热男人的天堂|
18禁动态无遮挡网站|
91午夜精品亚洲一区二区三区|
好男人视频免费观看在线|
欧美黄色片欧美黄色片|
日本猛色少妇xxxxx猛交久久|
亚洲精品国产av蜜桃|
亚洲精品日韩在线中文字幕|
a 毛片基地|
最近中文字幕2019免费版|
黄片播放在线免费|
kizo精华|
免费av中文字幕在线|
老女人水多毛片|
香蕉国产在线看|
777久久人妻少妇嫩草av网站|
久久久久久久久久久免费av|
国产成人av激情在线播放|
美女午夜性视频免费|
亚洲国产av影院在线观看|
热re99久久精品国产66热6|
在线看a的网站|
午夜老司机福利剧场|
欧美日本中文国产一区发布|
在线观看美女被高潮喷水网站|
欧美在线黄色|
精品久久蜜臀av无|
丝瓜视频免费看黄片|
亚洲人成电影观看|
最近2019中文字幕mv第一页|
亚洲国产精品一区二区三区在线|
日韩欧美精品免费久久|
videosex国产|
午夜日韩欧美国产|
久久久久精品人妻al黑|
欧美日韩视频高清一区二区三区二|
秋霞伦理黄片|
自拍欧美九色日韩亚洲蝌蚪91|
国产在线一区二区三区精|
久久精品亚洲av国产电影网|
三级国产精品片|
亚洲国产精品一区二区三区在线|
高清欧美精品videossex|
国产免费现黄频在线看|
青青草视频在线视频观看|
免费看不卡的av|
欧美日韩亚洲国产一区二区在线观看
|
国产又爽黄色视频|
免费观看a级毛片全部|
精品少妇一区二区三区视频日本电影
|
国产探花极品一区二区|
国产综合精华液|
少妇的逼水好多|
亚洲国产欧美在线一区|
日本欧美视频一区|
中国三级夫妇交换|
精品人妻一区二区三区麻豆|
美女国产视频在线观看|
亚洲少妇的诱惑av|
99热网站在线观看|
精品亚洲成a人片在线观看|
欧美日韩精品成人综合77777|
国产黄色视频一区二区在线观看|
午夜福利网站1000一区二区三区|
中文乱码字字幕精品一区二区三区|
看十八女毛片水多多多|
天堂8中文在线网|
一个人免费看片子|
永久网站在线|
国精品久久久久久国模美|
人妻一区二区av|
亚洲国产精品一区三区|
国产成人午夜福利电影在线观看|
国产高清国产精品国产三级|
亚洲精华国产精华液的使用体验|
最新中文字幕久久久久|
国产深夜福利视频在线观看|
精品一区二区三区四区五区乱码
|
毛片一级片免费看久久久久|
久久久国产精品麻豆|
av在线播放精品|
99国产精品免费福利视频|
91久久精品国产一区二区三区|
秋霞伦理黄片|
久久ye,这里只有精品|
亚洲精品久久成人aⅴ小说|
在线观看三级黄色|
丝袜在线中文字幕|
精品福利永久在线观看|
啦啦啦视频在线资源免费观看|
欧美成人精品欧美一级黄|
久久久国产精品麻豆|
国产精品欧美亚洲77777|
婷婷成人精品国产|
色网站视频免费|
亚洲欧洲精品一区二区精品久久久
|
亚洲精品国产一区二区精华液|
97在线人人人人妻|
中国三级夫妇交换|
波多野结衣av一区二区av|
18禁裸乳无遮挡动漫免费视频|
乱人伦中国视频|
久久精品国产自在天天线|
另类精品久久|
中文字幕人妻熟女乱码|
久久人人97超碰香蕉20202|
av福利片在线|
久久久久久久国产电影|
看非洲黑人一级黄片|
国产一级毛片在线|
免费观看a级毛片全部|
美女视频免费永久观看网站|
久久精品国产自在天天线|
纯流量卡能插随身wifi吗|
欧美日韩精品成人综合77777|
欧美成人精品欧美一级黄|
欧美人与性动交α欧美精品济南到
|
国产伦理片在线播放av一区|
人人妻人人添人人爽欧美一区卜|
精品酒店卫生间|
91精品国产国语对白视频|
性高湖久久久久久久久免费观看|
精品少妇内射三级|
夫妻性生交免费视频一级片|
欧美国产精品va在线观看不卡|
久久精品国产亚洲av高清一级|
中文字幕精品免费在线观看视频|
狠狠婷婷综合久久久久久88av|
av电影中文网址|
肉色欧美久久久久久久蜜桃|
夜夜骑夜夜射夜夜干|
黄频高清免费视频|
曰老女人黄片|
freevideosex欧美|
成人二区视频|
久久久久精品久久久久真实原创|
亚洲图色成人|
欧美精品国产亚洲|
h视频一区二区三区|
97在线视频观看|
蜜桃在线观看..|
久久午夜综合久久蜜桃|
亚洲男人天堂网一区|
在线观看美女被高潮喷水网站|
亚洲在久久综合|
97在线视频观看|
一级爰片在线观看|
搡女人真爽免费视频火全软件|
男人爽女人下面视频在线观看|
黄片小视频在线播放|
可以免费在线观看a视频的电影网站
|
久久国产亚洲av麻豆专区|
少妇的逼水好多|
一级毛片电影观看|
国产精品二区激情视频|
色播在线永久视频|
亚洲欧美精品自产自拍|
欧美日韩精品网址|
2022亚洲国产成人精品|
超碰97精品在线观看|
av福利片在线|
国产亚洲精品第一综合不卡|
2018国产大陆天天弄谢|
a级片在线免费高清观看视频|
久久99热这里只频精品6学生|
大香蕉久久网|
日韩免费高清中文字幕av|
亚洲av日韩在线播放|
我要看黄色一级片免费的|
欧美日韩综合久久久久久|
亚洲 欧美一区二区三区|
成人午夜精彩视频在线观看|
成人国产麻豆网|
一区二区三区激情视频|
成人免费观看视频高清|
成人影院久久|
丝袜喷水一区|
免费播放大片免费观看视频在线观看|
婷婷色av中文字幕|
久久久久精品久久久久真实原创|
久久久a久久爽久久v久久|
精品午夜福利在线看|
国产成人午夜福利电影在线观看|
免费观看性生交大片5|
av有码第一页|
亚洲综合精品二区|
日韩一本色道免费dvd|
性色av一级|
国产男女超爽视频在线观看|
人人妻人人添人人爽欧美一区卜|
一区福利在线观看|
各种免费的搞黄视频|
伊人久久国产一区二区|
哪个播放器可以免费观看大片|
人妻少妇偷人精品九色|
国产精品av久久久久免费|
91精品国产国语对白视频|
亚洲精品美女久久久久99蜜臀
|
中文天堂在线官网|
亚洲精品在线美女|
亚洲国产av影院在线观看|
韩国精品一区二区三区|
国产福利在线免费观看视频|
精品少妇内射三级|
成年人免费黄色播放视频|
欧美少妇被猛烈插入视频|
午夜影院在线不卡|
久久久久久伊人网av|
国产深夜福利视频在线观看|
777米奇影视久久|
国产成人午夜福利电影在线观看|
日日爽夜夜爽网站|
成年美女黄网站色视频大全免费|
一边摸一边做爽爽视频免费|
视频区图区小说|
国产亚洲av片在线观看秒播厂|
www.精华液|
国产成人一区二区在线|
丝袜美足系列|
国产福利在线免费观看视频|
国产亚洲一区二区精品|
精品久久久久久电影网|
午夜免费观看性视频|
黄色怎么调成土黄色|
99精国产麻豆久久婷婷|
丝袜脚勾引网站|
中文欧美无线码|
久久精品国产鲁丝片午夜精品|
日韩三级伦理在线观看|
尾随美女入室|
午夜福利视频精品|
满18在线观看网站|
另类精品久久|
av片东京热男人的天堂|
999久久久国产精品视频|
一级毛片 在线播放|
一区福利在线观看|
天美传媒精品一区二区|
国产熟女欧美一区二区|
午夜激情av网站|
婷婷色麻豆天堂久久|
婷婷成人精品国产|
亚洲成国产人片在线观看|
国产午夜精品一二区理论片|
中文字幕av电影在线播放|
国产欧美亚洲国产|
久久99热这里只频精品6学生|
欧美+日韩+精品|
有码 亚洲区|
黄片小视频在线播放|
嫩草影院入口|
久久久久久久久久久久大奶|
久久精品夜色国产|
成人毛片60女人毛片免费|
成年人午夜在线观看视频|
男女免费视频国产|
欧美 亚洲 国产 日韩一|
精品国产乱码久久久久久男人|
丰满少妇做爰视频|
久久女婷五月综合色啪小说|
少妇猛男粗大的猛烈进出视频|
欧美激情 高清一区二区三区|
www.精华液|
久久这里有精品视频免费|
久久久久国产一级毛片高清牌|
欧美精品高潮呻吟av久久|
桃花免费在线播放|
韩国精品一区二区三区|
国产国语露脸激情在线看|
九九爱精品视频在线观看|
菩萨蛮人人尽说江南好唐韦庄|
狠狠精品人妻久久久久久综合|
亚洲欧洲国产日韩|
成年动漫av网址|
国产日韩一区二区三区精品不卡|
国产午夜精品一二区理论片|
成人影院久久|
亚洲视频免费观看视频|
久久午夜综合久久蜜桃|
中文字幕人妻丝袜一区二区
|
精品一区在线观看国产|
欧美97在线视频|
国产精品人妻久久久影院|
男人添女人高潮全过程视频|
成人国产av品久久久|
国产老妇伦熟女老妇高清|
欧美亚洲 丝袜 人妻 在线|
亚洲欧美日韩另类电影网站|
亚洲一区二区三区欧美精品|
a 毛片基地|
日产精品乱码卡一卡2卡三|
在线观看www视频免费|
日本av免费视频播放|
久久久久久人妻|
亚洲成国产人片在线观看|
欧美97在线视频|
www.精华液|
a级毛片黄视频|
国产白丝娇喘喷水9色精品|
亚洲成人手机|
夫妻性生交免费视频一级片|
免费日韩欧美在线观看|
这个男人来自地球电影免费观看
|
日本欧美国产在线视频|
午夜日本视频在线|
a 毛片基地|
91国产中文字幕|
国产精品一二三区在线看|
99香蕉大伊视频|
自线自在国产av|
可以免费在线观看a视频的电影网站
|
欧美 亚洲 国产 日韩一|
午夜福利网站1000一区二区三区|
久久久久精品性色|
亚洲人成电影观看|
精品99又大又爽又粗少妇毛片|
免费不卡的大黄色大毛片视频在线观看|
日本欧美视频一区|
亚洲精品国产色婷婷电影|
国产成人精品福利久久|
一级黄片播放器|
国产一区亚洲一区在线观看|
伦理电影大哥的女人|
国产乱来视频区|
欧美精品国产亚洲|
国产精品一区二区在线观看99|
激情视频va一区二区三区|
av网站在线播放免费|
老司机影院毛片|
在线观看www视频免费|
国产男女内射视频|
波野结衣二区三区在线|
国产无遮挡羞羞视频在线观看|
又粗又硬又长又爽又黄的视频|
波野结衣二区三区在线|
亚洲精品中文字幕在线视频|
欧美中文综合在线视频|
国产有黄有色有爽视频|
在线观看www视频免费|
91aial.com中文字幕在线观看|
涩涩av久久男人的天堂|