《液压与气动》“摘要”写作注意事项

140液压与'动2019年第8期Experimental Study on Friction Force of Actuator[D].Hangzhou:Zhejiang University,2018.[8]王洁，苏东海,官忠范•液压传动系统'M].北京:机械工业出版社,2015.WANG Jce,SU Donghac,GUAN Zhongoan.Hydaaulcc Transmission System[M].Beijing:Mechanical IndusSy Pae s,2015.[9]王春行•液压控制系统[M].北京:机械工业出版, 2004.WANG Chunhang.Hydraulic Control System[M].Beijing:MechanccalIndusiayPaess,2004.[10]刘亚波，成建平,姚平喜.一种新型液压制动阀的原理与性能研究[J].液压与气动,2014,(10)$103-106.LIUYabo,CHENG Jcanpcng,YAO Pcngxc.Siudyon ihePacnccpleand PeaooamanceooaNewHydaaulccBaakeValee[J].ChcneseHydaaulccs&Pneumaiccs,2014,(10):103-106.[11]刘顺斌.液压支架立柱试验台新测试功能研究[J].煤矿机械,2018,39(1):27-28.LIUShunbcn.Reseaach on NewTesiFuncicon ooHydaaulccSuppoaiColumn TesiBench[J].CoalMcneMachcneay,2018,39(1):27-28.[12]王凯，李扬眉，姜小玉，等.疲劳试验中高频正弦运动作动筒所需流量的分析与计算[J].液压与气动,2016,(4):88-91.WANGKac,LIYangmec,JIANG Xcaoyu,eial.Analyscsand Calculaicon ooFlow Requcaed ooa Hcgh FaequencyScnusocdalMoicon Aciuaioacn FaicgueTesi[J].ChcneseHydaaulccs&Pneumaiccs,2016,(4):88-91.[13]廖辉,乔东凯.基于LS-SVM液压缸泄漏故障诊断方法的研究[J].机床与液压,2017,45(15)：184-187.LIAO Hut,QIAO Dongkai.Research on HydraulicCylcndeaLeakageFauliDcagnoscsMeihod Based on LS-SVM[J].Machine Tool and Hydraulic,2017,45( 15):184-187.[14]李志丰，胡思玉，闫宝和.液压缸性能测试试验台的研究[J].机床与液压,2016,44(13):116-119.LIZhcoeng,HUScyu,YANBaohe.Reseaach on HydaaulccCylcndeaPeaooamanceTesiBench[J].MachcneToolandHydraulic,2016,44(13):116-119.[15]杨荣荣，付永领,马俊功，等.飞机前轮转弯机构寿命试验测控系统设计[J].液压与气动,2015,(5):121-126.YANG Rongaong,FU Yonglcng,MA Jungong,eial.Descgn ooLcoeTesiand ConiaolSysiem ooaAcacaaoiFaoniWheelSieeacng Mechancsm[J].ChcneseHydaaulccs&Pneumaiccs,2015,(5):121-126.[16]钱老红，王占辉.液压缸内泄漏检测方法的改进[J].液压气动与密封,2016,36(3):65-67.QIAN Laohong,WANG Zhanhuc.ImpaoeemeniooLeakDeiecicon Meihodscn HydaaulccCylcndeas[ J].HydaaulccsPneumaiccs&Seals,2016,36(3):65-67.引用本文：赵孟文，崔俊如,樊泽明，等.清洗油封一体化试验装置的设计[J].液压与气动,2019,(8):135-140.ZHAO Menywen,CUI Junru,F AN Zeming,of al.Design of Inteyrated Test Device for Cleaning Oil Seal[J].Chinese Hydraulics& Pneumaicc,,2019,(8):135-140.《液压与气动》“引言”与“结论”写作要求引言，简要说明研究的目的、范围、相关领域的前人工作与现状(也称文献综述，尤其近年的发展现状和文献)，理论依据、试验基础和研究方法，作者的意图、预期的结果及其作用和意义。

《液压与气动》投稿须知
佚名
【期刊名称】《液压与气动》
【年(卷),期】2022(46)6
【摘要】主要介绍液压传动与气压传动技术研究及其应用。

目前《液压与气动》杂志设有综述、理论研究、工程技术、综合应用等栏目。

一、投稿要求和注意事项作者所投稿件应符合以下要求:(1)文章的内容要求符合党和国家的方针政策,为液压气动行业发展服务,达到国内或国际先进水平;同时应具有创新性,有一定的个人见解和前瞻性,综述性稿件应注意时效性。

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【正文语种】中文
【中图分类】G23
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8液％与气（2017年第12期(续表2) 0/m mg • cycle 1&/K"M P a-/JExp 130.10.1340.70.2372137.279.8 Exp 140.10. 126338. 10.233135.380.9 Exp 150.10. 148335.70.2316134.581.5等温--2890.1934109.61004结论本研究采用0.1〜0. 3 mm直径的喷嘴、2〜5 MPa 的高压水,产生了 10〜100 !=直径水雾，对压缩空气 进行冷却，减少压缩功的消耗。

对压缩缸内压力和体 积进行测量，并基于状态方程,得到空气和水雾的温 度，温度测量的响应时间达到5 m,实验采用压缩缸的体积为0.94L,体积压缩比为 2,压缩时长是250 m,压缩空气温升下降至32.4 f (绝热92& f)。

压缩效率从82&@上升到88&@, 水雾发生消耗的功占压缩功的2@左右。

因此，水雾 冷却准等温压缩可以实现压缩效率的提高。

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