XiaoMi-AI文件搜索系统
World File Search SystemBhosale
目录
(Covexin) Whole-Virion Inactivated SARS-COV-2 Vaccine for Serological Surveys Pateek Singh, rajat ujjainiya, satyartha prakash, Salwa Naushin, Viren Sardana, Nitin Bhatheja Pratap Singh, Joydeb Barman, Kartik Kumar, Saurabh Gayali, Raju Khan, Birendra Singh Rawat,Karthik Bharadwaj Tallapaka,Mahesh Anumalla,Amit Lahi,Susanta Kar,Vivek Bhosale Bhosale Srivastava,Madhav Nilantth Mugale,C.P。 Pandey, Shaziya Khan, Shivani Katiyar, Desh Raj, Sharmeen Ishteyaque, Sonu Khanka, Ankita Rani, Promila, Jyotsna Sharma, Anuradha Seth, Mukul Dutta, Nishant Saurabh, Murugan VeerPandian, Ganesh Venkatachalam, Deepak Bansal, Dinesh Gupta, Prakash M. Halami, Muthukumar Serva Peddha, Ravindra P. Veranna Pal, Ranvijay Kumar Singh, Suresh Kumar Anandasadagopan, Parimala Karuppanan, Syed Nasar Rahman, Gopika Selvakumar, Subramanian Venkatesan, Malay Kumar Karmakar, Harish Kumar Sardana, Anamika Kothari, Devendra Singh Parihar, Anupmaa Thakur, Anas Saifi, Naman Gupta, Yogita Singh, Ritu Reddu, Rizul Gautam, Anuj Mishra, Avinash Mishra, Iranna Gogeri, Geethavani Rayasam, Yogendra Padwad, Vikram Patial, Vipin Hallan, Damanpreet Singh, Narendra tirpude,partha(Covexin) Whole-Virion Inactivated SARS-COV-2 Vaccine for Serological Surveys Pateek Singh, rajat ujjainiya, satyartha prakash, Salwa Naushin, Viren Sardana, Nitin Bhatheja Pratap Singh, Joydeb Barman, Kartik Kumar, Saurabh Gayali, Raju Khan, Birendra Singh Rawat,Karthik Bharadwaj Tallapaka,Mahesh Anumalla,Amit Lahi,Susanta Kar,Vivek Bhosale Bhosale Srivastava,Madhav Nilantth Mugale,C.P。Pandey, Shaziya Khan, Shivani Katiyar, Desh Raj, Sharmeen Ishteyaque, Sonu Khanka, Ankita Rani, Promila, Jyotsna Sharma, Anuradha Seth, Mukul Dutta, Nishant Saurabh, Murugan VeerPandian, Ganesh Venkatachalam, Deepak Bansal, Dinesh Gupta, Prakash M. Halami, Muthukumar Serva Peddha, Ravindra P. Veranna Pal, Ranvijay Kumar Singh, Suresh Kumar Anandasadagopan, Parimala Karuppanan, Syed Nasar Rahman, Gopika Selvakumar, Subramanian Venkatesan, Malay Kumar Karmakar, Harish Kumar Sardana, Anamika Kothari, Devendra Singh Parihar, Anupmaa Thakur, Anas Saifi, Naman Gupta, Yogita Singh, Ritu Reddu, Rizul Gautam, Anuj Mishra, Avinash Mishra, Iranna Gogeri, Geethavani Rayasam, Yogendra Padwad, Vikram Patial, Vipin Hallan, Damanpreet Singh, Narendra tirpude,parthaPandey, Shaziya Khan, Shivani Katiyar, Desh Raj, Sharmeen Ishteyaque, Sonu Khanka, Ankita Rani, Promila, Jyotsna Sharma, Anuradha Seth, Mukul Dutta, Nishant Saurabh, Murugan VeerPandian, Ganesh Venkatachalam, Deepak Bansal, Dinesh Gupta, Prakash M. Halami, Muthukumar Serva Peddha, Ravindra P. Veranna Pal, Ranvijay Kumar Singh, Suresh Kumar Anandasadagopan, Parimala Karuppanan, Syed Nasar Rahman, Gopika Selvakumar, Subramanian Venkatesan, Malay Kumar Karmakar, Harish Kumar Sardana, Anamika Kothari, Devendra Singh Parihar, Anupmaa Thakur, Anas Saifi, Naman Gupta, Yogita Singh, Ritu Reddu, Rizul Gautam, Anuj Mishra, Avinash Mishra, Iranna Gogeri, Geethavani Rayasam, Yogendra Padwad, Vikram Patial, Vipin Hallan, Damanpreet Singh, Narendra tirpude,partha
高级网格尺度存储技术
本研究中使用的数据,信息和图表是基于从各种来源获得的数据,值得庆幸的是。已经采取了每项护理,以确保数据正确,一致和尽可能地完成并适当提及。但是,分配本质的时间和资源的限制并不排除错误,遗漏等的可能性。在数据中,因此在数据中,因此在报告准备中。封面上的照片是Anon。使用本研究报告的内容是免费的,但参考如下:Kumar A,Arora P,Jain H,Sharma AK,Bhosale AC,Rakshit D和Singh R; “高级网格尺度储能技术”,印度研究,2023年10月。
不同的微加工制造工艺......
Yogesh M.Motey 先生 Purnashti A. Bhosale 女士 (电子与电信系) (电子系) GHRIET,那格浦尔 PIGCE,那格浦尔 yogesh.motey@gmail.com bhosalepurnashti@gmail.com 摘要 — 微机电系统或 MEMS 是结合电气/电子和机械元件的集成微型设备或系统。MEMS 技术的快速发展带来了许多伟大的想法和物理、化学和生物传感器的发展。如果说半导体微加工是第一次微制造革命,那么 MEMS 就是第二次革命。本文反映了有关该技术的最新研究成果。本文回顾了表面微加工、体微加工、LIGA 微加工和激光微加工等工艺,以展示每种工艺的特点并进行比较。关键词——微机电、表面微加工、高纵横比微加工、LIGA、体微加工、激光微加工。
apl of 2022.pdf
2023年第36号上诉,其授权代表Mahindra Towers G.M.Bhosale Marg,P.K。 kurnechowk,孟买沃利(Worli) - 印度马哈拉施特拉邦400018 拉贾斯坦邦电力监管委员会,通过其秘书,萨哈卡·玛格(Sahakar Marg)的Vidhyutviniyamakbhawan,位于斋浦尔302001的州汽车车库附近 印度太阳能公司通过其董事长,第6楼,B板,NBCC办公室6楼,塔楼-2,East Kidwai Nagar,新德里 - 110023 - 110023…受访者2号3. Rajasthan Urja Vikas Nigam Limited,通过其主席Vidyutbhawan,Jyoti Nagar,Janpath,Japath,Jaipur,Rajasthan - 302005…受访者第3号4。 Fortum Solar Plus Private Limited通过其董事1 A,Vandana建筑物1 A,新德里托尔斯泰MARG 11号 - 110001…受访者4Bhosale Marg,P.K。kurnechowk,孟买沃利(Worli) - 印度马哈拉施特拉邦400018拉贾斯坦邦电力监管委员会,通过其秘书,萨哈卡·玛格(Sahakar Marg)的Vidhyutviniyamakbhawan,位于斋浦尔302001的州汽车车库附近印度太阳能公司通过其董事长,第6楼,B板,NBCC办公室6楼,塔楼-2,East Kidwai Nagar,新德里 - 110023 - 110023…受访者2号3.Rajasthan Urja Vikas Nigam Limited,通过其主席Vidyutbhawan,Jyoti Nagar,Janpath,Japath,Jaipur,Rajasthan - 302005…受访者第3号4。Fortum Solar Plus Private Limited通过其董事1 A,Vandana建筑物1 A,新德里托尔斯泰MARG 11号 - 110001…受访者4
第1个马拉松优点列表2023.xlsx
座位号。名称数学int。科学总计全印度排名区域102318735 SAEE VIJAY BHOSALE 50 25 100 1st Kolhapur 102319214 Annapurna Dinesh Jalgaonkar 50 2599 2nd Jalgaon 102318482 Razvardhan Mahendra Razvardhan Mahendra Supekar1 24 299 3rd Otur 102317947 Ajit JADHAV 49 259 25959 4th Kundal 102318745 Vardhan Amol Kole 49 259 25959594TH KOLHAPUR 1023152229 102315806 krushnendu raghvendra patil 50 23 25 98 7th gadhinglaj 102319524 Sulbha Shivprasad Prasade 50 23 25 98 7th Pune 102318522 Ridhima Vishal Shinde 49 25 24 98 98 98 10231753 Swarali Adinath Patil 49 25 2498 9th Jaysingpur 102318543 Divyangana Dinkar Parit 49 25 2498 9th Kolhapur 102315359 Renu Bhimashankar 49 25 25 Vijay Ingale 48 25 98 13 PALI 102319732 LALIT RUPESH KAMBLE 48 25 98 13孟买102315636 Shreraj Rahul Kinikar 50 23 97 15th Bhilawadi 102317974 Sai Mai Mai Maij Kadam 50 23 97 23 97 15th Phaltan 102319815 Dnnyanesh Sada Kurkumbe 50 24 23 97 15th Sangola 102316061 Nidhi Jitendra Kamble 50 23 24 97 18th Ratnagiri 102311941 Swayam 50 Anavi Amit Pachore 50 2397 18th Nandre 102317999999999999999999999999999999999999999999999999999999999999999999999999999999999999999年447 Girish Karn 50 22 25 97 21st Kolhapur 102316971 Aaisha Jamir Shaikh 492 25 23 23 97 23rd devrukh 102319629 Lalita Hemant Chavan 49 25 23 97 23rd Pune
第三std Marathi功绩2023.xlsx
座位号。名称数学int。科学总计全印度等级面积302303517 Pournima Sagar Jagdale 50 25 100 1st Paithan 30239271 Sakshi Manish MANISH MISAL 50 2599233335912 AROHI AMOL GURAV 50 249229 3RD Gadhinglaj 302338455 Aditya Vinod Chavan 50 249 3rd Tasgaon 302338851 Amey Amoy Amol Pawar 50 24939 3RD PHALTAN 302303619 SARANYA VINAY JOSHILKAR 50 249 249 3RD KOLHAPUR 3RD KOLHAPUR 302230379 HERMAMB RAVINDRARRA Farakte 495 25959 7th Mumbai 302303327 hindvi kalesh naniwadekar 49 259 259 7th nanded 302337928 Jidnesh PANALK PANALLAR 49 259 7th Pune 302338007 Almisha Javed Mulla 49 259 259 259 30233997 Aditya pinam Khot 50 25 23 98 11th Sawantwadi 302335971 Pritam Ganesh Kharat 50 25 23 98 11th gadinglaj 302337828 Rajeshvari Shrikrishna shrikrishna shrikrishna bhosale 50 302335911 Swara Prashant Gurav 50 24 98 14th gadhinglaj 302338397 Soham Subhash Bansode 50 24 98 14 98 Mandangad 302338535 Aditi Chetan 50 24 98 98 14 98 14th Savlaj 30238582 Anjali Dilip更多50 24 2498 14th Yellow Shahuwadi 302339250 Vaishnavi Rajkumar Shirkule 50 24 98 14th Karad 302336456 Swara Ganesh Rode 50 24 98 Janavale Guhagar Guhagar 3023333333335 Rajveer Birappa Kurni 50 24 98 14th Lanja 302335515 Arnav Rajaram Bhise 50 23 25 98 21st Kanedi 302335921 Rudra Vishal Utture 49 25 2498 22nd Gadhinglaj 3023338710 Pranavi Kiran kiran Yadav 49 25 2498 2498 22nd Kadegand kadegand kadega ga nd kadegagand kadegand kadea 302339884 Aayush Rajendra Tounddakar 49 25 2498 22nd Kolhapur
有关发电瓷砖的研究
摘要:在现代时代,对能源的不断提高强调了对开创性创新的需求。本文试图通过转化通过简单的行动进入可持续的电力来源而产生的非常规能源来利用这一必要性。电力发生器瓷砖是一种新颖而生态的友好能量收集系统,旨在利用人类的运动来发电。两个12V DC电动机集成到行走表面下的机械结构中,有效地将机械能从脚步转换为电能。生成的电源存储在紧凑而轻巧的3.7V Lipo电池中,以方便存放。可视化发电过程是通过合并两个LED来促进的,从而提供了发电的真实时间。该便携式解决方案提供了一种从人类运动中收集能量的实用手段,对需要OFF -GRID功率来源的各种应用具有希望。凭借其创新的设计,电力发电机瓷砖是一种可持续的解决方案,可以解决不断增长的全球能源需求,尤其是在传统电源有限或不可用的地区。关键字:人类运动能量收集,电能转换,压力 - 触发机制。1。在我们当代社会中的引言中,能源和权力的不可或缺性比以往任何时候都更加明显。随着全球对能源的需求继续其上升轨迹,众多传统能源的耗尽和浪费构成了重大挑战。2。解决这一问题时,提出范式转向朝着利用人类运动过程中脚力产生的能量的范式转变具有重要优势。这个主张在人口稠密的国家(如印度)中获得了特别的意义,那里的交通流量,铁路站,公共汽车摊位和庙宇始终始终见证人满为患,有数百万的人永久运动。尽管这种动能源固有的巨大潜在潜在的潜力,但目前尚未开发,使其成为变革性发明的主要候选人。电力发生器瓷砖作为开创性的解决方案出现,通过捕获通过人类脚步产生的动能来引入有关可持续能量的新观点。采用了两个12V DC电动机,该技术巧妙地集成了系统,该技术擅长转换在行走中产生的机械能,进入宝贵的电力来源。利用的能量可在轻巧的3.7V Lipo电池中找到房屋,而两个LED的结合提供了视觉上令人信服的真实 - 发电过程的时间显示。这项创新及其可移植性和效率,不仅倡导生态友好的做法,而且还使自己成为可行的网格电源 - 网格电源 - 赋予个人通过简单而日常的步行行为来为能源生产做出贡献。文献综述1)脚步发电机的设计-1] Bhosale P. A.等人。在本文中,作者使用了简单的驱动机制,例如机架和小齿轮组件。他们已经讨论了各种应用程序和进一步的扩展。控制机制带有机架和小齿轮; D. C发电机,电池和LED条以显示输出。发表的论文发表于:2017年6月。