登录
首页 » Others » SendMail

SendMail

于 2013-01-14 发布 文件大小:316KB
0 220
下载积分: 1 下载次数: 6

代码说明:

  为了帮助站长朋友们推广,现放出XX邮件群发系统(集成QQ号码采集)beat1。使用说明如下: 1、解压后直接使用,需要.net2.0支持,如果没有安装请百度搜索下 2、请先配置好Data文件夹下的Title.txt(邮件标题),Content.txt(邮件内容) 3、请按规则配置好SendEmail.txt的发送邮箱内容,自己需要去多申请一些邮箱 4、打开软件开始使用时,请先导入邮箱,也就是SendEmail.txt文件 5、请先点击采集按钮,采集QQ邮箱放能发送 6、最后点邮件发送 7、为了防止被当成垃圾邮件和提高成功率,发送速度比较慢,多个邮箱轮流每7秒发送一封,请耐心等待 8、数据存在SendMail.mdb中,可手动去删除数据(In order to help the friends of stationmaster of promotion, now released XX bulk mail system ( integrated QQ number acquisition ) beat1. Use the following: In 1, directly after decompression using, need.Net2.0 support, if not installed please Baidu search 2, please first configured the Data folder under the Title.txt ( headers ), Content.txt ( mail ) 3, please follow the rules configured SendEmail.txt send mail content, you need to apply some of the mailbox 4, open the software use, please first into the mailbox, which is the SendEmail.txt file 5, please click the capture button, the QQ mailbox to send collection In 6, the last point send mail 7, in order to prevent being as spam and increase the success rate, to send the relatively slow speed, multiple mailboxes turns every 7 seconds to send a letter, please wait patiently In 8, the data in SendMail.mdb, can be to manually delete data)

下载说明:请别用迅雷下载,失败请重下,重下不扣分!

发表评论

0 个回复

  • matlab形成节点导纳矩阵的
    形成matlab中节点导纳矩阵的程序。可以帮助大家对导纳矩阵的形成有更进一步的了解。
    2020-12-11下载
    积分:1
  • 基于verilog的电梯系统设计
    一个电梯系统的课程设计,用verilog语言编写,包含基本的电梯运行逻辑,能够使用
    2020-12-12下载
    积分:1
  • 平面变压器3D仿真资料
    采用COMSOL软件,对平面变压器的仿真过程进行叙述,让大家了解平面变压器的仿真流程,是个很好的指导教材Solved with COMSOL Multiphysics 5.0Results and discussionThe magnetostatic analysis yields an inductance of 0. 1l mH and a dc resistance of0. 29 mQ2. Figure 2 shows the magnetic flux density norm and the electric potentialdistributionvolume: Coil potentiaL()Volume: Magnetic flux density norm (t▲0.07▲2.88×10-42.51.50.03050.01V656×107v0igure 2: Magnetic flux density norm and electric potential distribution for themagnetostatic analysisIn the static (DC) limit, the potential drop along the winding is purely resistive andcould in principle be computed separately and before the magnetic flux density iscomputed. When increasing the frequency, inductive effects start to limit the currentand skin effect makes it increasingly difficult to resolve the current distribution in thewinding. At sufficiently high frequency, the current is mainly flowing in a thin layernear the conductor surface. When increasing the frequency further. capacitive effectscome into play and current is flowing across the winding as displacement currentdensity. When going through the resonance frequency, the device goes from behavingas an inductor to become predominantly capacitive. At the self resonance, the resistivelosses peak due to the large internal currents Figure 4 shows the surface current3 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.0distribution atl MHz. Typical for high frequency the currents are displaced towardsthe edges of the conductor.freq(1)=1.0000E6_Surfaee: Surface-current density norm (A/)▲18618Q16010¥1.02Figure 3: Surface current density at I MHz (below the resonance frequency)Figure 4 shows how the resistive part of the coil impedance peaks at the resonancefrequency near 6MHz whereas Figure 5 shows how the reactive part of the coiimpedance changes sign and goes from inductive to capacitive when passing throughthe resonance4 MODELING OFA3DINDUCTORSolved with COMSOL Multiphysics 5.0Global: Lumped port impedance(Q2)d port impedance7.5G6.583275655545352510.10.20.30.40.509igure 4: Real part of the electric potential distribution5 MODELING OF A INDUCTORSolved with COMSOL Multiphysics 5.0Global: Lumped port impedance(Q2)35000Lumped port impedance200001000050000500010000-1500020000250000.10.20.30.40.50.60.70.809Figure 5: The reactive part of the coil impedance changes sign hen passing through theresonance frequency, going from inductive to capacitiveModel library path: ACDC_Module/Inductive_ Devices_and_coils/inductor 3dFrom the file menu. choose newNEWI In the new window click model wizardMODEL WIZARDI In the model wizard window click 3D2 In the Select physics tree, select AC/DC> Magnetic Fields(mf)3 Click Add4 Click StudyMODELING OF A3D NDUCTORSolved with COMSOL Multiphysics 5.05 In the Select study tree, select Preset Studies>StationaryGEOMETRYThe main geometry is imported from file. Air domains are typically not part of a CaDgeometry so they usually have to be added later. For convenience three additionaldomains have been defined in the CAd file. These are used to define a narrow feed gapwhere an excitation can be appliedport l(impl)I On the model toolbar, click Import2 In the Settings window for Import, locate the Import section3 Click Browse4 Browse to the models model library folder and double-click the filenductor 3d. mphbinSphere /(sphl)I On the Geometry toolbar, click Sphere2 In the Settings window for Sphere, locate the Size section3 In the Radius text field, type 0.2ick to expand the Layers section. In the table, enter the following settingsLayer nameThickness(m)ayer0.055 Click the Build All Objects buttonForm Union(fin)i On the Geometry toolbar, click Build AllClick the Zoom Extents button on the Graphics toolbar7 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.03 Click the Wireframe Rendering button on the Graphics toolbarThe geometry should now look as in the figure below0.1-0.10.20.0.0.1y0.0.2Next, define selections to be used when setting up materials and physics Start bdefining the domain group for the inductor winding and continue by adding otheruseful selectionsDEFINITIONSExplicitI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Winding3 Select Domains 7,8 and 14 onlyI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Gap3 Select domain 9 onlI On the Definitions toolbar, click Explicit8 MODELING OF A3DINDUCTORSolved with COMSOL Multiphysics 5.02 In the Settings window for Explicit, in the Label text field, type core3 Select Domain 6 onlyExplicit 4I On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type InfiniteElements3 Select Domains 1-4 and 10-13 onlyExplicit 5I On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Non-conducting3 Select Domains 1-6 and 9-13 onlyI On the Definitions toolbar, click Explicit2 In the Settings window for Explicit, in the Label text field, type Non-conductingwithout Ie3 Select Domains 5, 6, and 9 only.Infinite Element Domain /(iel)Use infinite elements to emulate an infinite open space surrounding the inductorI On the definitions toolbar click Infinite element domain2 In the Settings window for Infinite Element Domain, locate the Domain Selectionsection3 From the Selection list. choose Infinite Elements4 Locate the Geometry section From the Type list, choose SphericalNext define the material settingsADD MATERIALI On the Model toolbar, click Add Material to open the add Material window2 Go to the Add material window3 In the tree, select AC/DC>Copper.4 Click Add to Component in the window toolbar9 MODELING OF A 3D INDUCTORSolved with COMSOL Multiphysics 5.0MATERIALSCopper(mat/)I In the Model Builder window, under Component I(comp l)>Materials click Copper(matD)2 In the Settings window for Material, locate the Geometric Entity Selection section3 From the Selection list, choose windingADD MATERIALI Go to the Add Material window2 In the tree. select built-In>Air3 Click Add to Component in the window toolbarMATERIALSAir(mat2I In the Model Builder window, under Component I(comp l)>Materials click Air(mat2)2 In the Settings window for Material, locate the Geometric Entity Selection section3 From the Selection list, choose Non-conductingThe core material is not part of the material library so it is entered as a user-definedmateriaMaterial 3(mat3)I In the Model Builder window, right-click Materials and choose Blank Material2 In the Settings window for Material, in the Label text field, type Core3 Locate the geometric Entity Selection section4 From the selection list choose Core5 Locate the Material Contents section. In the table, enter the following settingsPropertName Value Unit Property groupElectrical conductivity sigma0S/IBasicRelative permittivity epsilonrBasicRelative permeability mur1e3Basic6 On the model toolbar. click Add Material to close the Add Material windowMAGNETIC FIELDS (MF)Select Domains 1-8 and 10-14 only0MODELING OF A 3D INDUCTOR
    2020-12-10下载
    积分:1
  • 数字上摄影测量最小二乘匹配
    先用点特征提取算子,再粗匹配,最后使用最小二乘匹配,适合核线影像
    2020-11-30下载
    积分:1
  • 潮流计算IEEE4、5、14、30、57、118、300节点系统
    文件为C++语言编写的潮流计算,采用牛顿法实现,内含IEEE4、5、14、30、57、118、300节点系统系统原始数据及潮流计算结果,还有详细的使用说明,经与《高等电力网络分析》(张伯明著2007版)附录对比,计算结果完全正确;个人觉得程序可扩展用遗传算法,禁忌搜索算法中;
    2020-12-06下载
    积分:1
  • 小波相对能量法分析(matlab实现说明代码)
    relative_energy的小波分析代码,可以用来特征分析,该文件是有国外权威学者发布的代码,引用时请注明Copyright (c) 2009, Guan Wenye All rights reserved.很好的资料
    2020-12-03下载
    积分:1
  • C8051F系列中文数据手册.zip
    【实例简介】C8051F系列中文数据手册,潘琢金译,包含各个型号,可供编程或学习入门时参考。
    2021-11-26 00:35:27下载
    积分:1
  • cnn 经典matlab代码
    卷积神经网络经典代码,非常详细,可直接运行
    2020-11-28下载
    积分:1
  • ORACLE DBA 简历如何写
    在我20多年的与数据库相关职业生涯中,我聘用和管理过50多位DBA,面试或评审过至少几千份应聘者的简历。老实说,每次面试都会使我大吃一惊。但是,我注意到很多的确和我相关的东西。应聘者除了将他们自己“卖”给一份好工作外,IT人员今天还有了权利意识——即“比起我需要你,你更加需要我”这样的一种心理。市场状况使DBA从自信转变成自傲。首先我在这里提醒你,这样的态度只会让你自己身陷泥潭!
    2020-12-03下载
    积分:1
  • LabVIEW数据采集DAQ实例源代码,菜鸟飞跃的台阶!
    LabVIEW 数据采集 DAQ 实例 源代码
    2021-05-06下载
    积分:1
  • 696516资源总数
  • 106914会员总数
  • 0今日下载