供应德国倍福
BECKHOFF(现场信号产品) KL3312BECKHOFF(现场信号产品) KL3202BECKHOFF(现场信号产品) KL4002BECKHOFF(现场信号产品) KL4X32BECKHOFF(现场信号产品) KL4X12BECKHOFF(现场信号产品) KL4022BECKHOFF(现场信号产品) KL3061BECKHOFF(现场信号产品) KL3001BECKHOFF(现场信号产品) KM2004BECKHOFF(现场信号产品) KM10X8BECKHOFF(现场信号产品) KM2008BECKHOFF(现场信号产品) EL10X2BECKHOFF(现场信号产品) EL1502BECKHOFF(现场信号产品) EL20X2BECKHOFF(现场信号产品) EL1502BECKHOFF(现场信号产品) EL20X2BECKHOFF(现场信号产品) EL25020BECKHOFF(总线耦合器产品) BK3520BECKHOFF(总线耦合器产品) BK4020BECKHOFF(总线耦合器产品) BK5120BECKHOFF(总线耦合器产品) BK5220BECKHOFF(总线耦合器产品) BK7420BECKHOFF(总线耦合器产品) BK7520BECKHOFF(总线耦合器产品) BK3150BECKHOFF(总线耦合器产品) BK5150BECKHOFF(现场总线端子盒产品) IL230X-B810BECKHOFF(现场总线端子盒产品) IL230X-B900BECKHOFF(现场总线端子盒产品) IL230X-B901BECKHOFF(现场总线端子盒产品) IL230X-C310BECKHOFF(现场总线端子盒产品) IL230X-C318BECKHOFF(现场总线端子盒产品) IL230X-C800BECKHOFF(现场总线端子盒产品) IL230X-C810光导总线产品 AM3000光导总线产品 AL2XXXFCXXXX系列PC现场总线接口 FC2001-0000FCXXXX系列PC现场总线接口 FC3101-0000FCXXXX系列PC现场总线接口 FC5101-0002FCXXXX系列PC现场总线接口 FC5201-0000FCXXXX系列PC现场总线接口 FC5201-0002FCXXXX系列PC现场总线接口 FC7501-0000FCXXXX系列PC现场总线接口 FC7502-0000FCXXXX系列PC现场总线接口 FC9002-0000FCXXXX系列PC现场总线接口 FC9004-0000ES20XX系列以太网交换机 ES2008ES21XX系列以太网交换机 ES2016ES22XX系列以太网交换机 AX2003ES23XX系列以太网交换机 AX2006 ES24XX系列以太网交换机 AX2010 ES25XX系列以太网交换机 AX2020 ES26XX系列以太网交换机 AX2503 同步伺服电机AM2004 AM227M-0000同步伺服电机AM2005 AM212M-0001同步伺服电机AM2006 AM227L-0000同步伺服电机AM2007 AM227L-0001同步伺服电机AM2008 AM237S-0000同步伺服电机AM2009 AM237S-0001同步伺服电机AM2010 AM237M-0000同步伺服电机AM2011 AM237M-0001同步伺服电机AM2012 AM237L-0000AM3009系列同步伺服电机 AM3032-wDyzAM3010系列同步伺服电机 AM3033-wEyzAM3011系列同步伺服电机 AM3041-wCyzAL2000,AL2400,AL2818系列线性伺服电机 AL2910 AL2000,AL2400,AL2819系列线性伺服电机 AL2920AL2000,AL2400,AL2820系列线性伺服电机 AL2930
Z1S6B30-4X/V德国力士乐
武汉翔升达机电设备有限公司
电话:18627799306/
传真:
联系人:李京京 QQ:2605942261
DBDS10K-1X/400,DBDS6K1/315 ,DBDS10K1X/400, DBDS10G-1X/200 ,DBDS20K1X/200, DBDS20K1X/50,DBDS10K1X/315 ,DBDS10K18/25,DBDS6K-1X/100, DBDS10P1X/400, DBDS6K1X/315,DBDS10K1X/315 ,DBDS10P1X/200,DBDS6K121X/100 ,DBDS10-P-1X/200, DBDS10K18/25 ,DBDS10-P-1X/200,DBDS10K18/25, DBDS6P1X/ 315 ,DBDS10-P-1X/200 ,DBDS10K18/25, DBDS10P1X/200, DBDS6K121X/100,DBDS10-P-1X/200,DBDS10K18/25, DBDS10-P-1X/200, DBDS10K18/25, DN10DBDS-10K10/315 ,DBDS6K1X/315,DBDH10P/400,DBDH6P1X/315,DBDS30G1X/315,DBDS10P1X/200,DBDS6G1X/315,DBDS10K1X/315,DBDS20K1X/315, DBDS20P1X/200,DBDS20P10,DBDS30P1X/200V,DBDS30K1X/315V,DBDS30K1X/315,DBDS30K1X/25,DBDS25G1X/315,DBDA20P1X/25,DBDA20G1X/25,DBDA20K1X/100,DBDA20K1X/25V,DBDH20K1X/50,DBDA15G1X/25,DBDA10P1X/, DBDA10G1X/630V,DBDA10G1X/25V,DBDA10K1X/400,DBDH10P1X/50V,DBDH10G1X/315V,DBDS10P1X/25V,DBDS10K1X/315V,DBDA6P1X/25,DBDA6G1X/315V,DBDS6P1X/200V,DBDS6G1X/315,DBDH25G1X/50,DBDS20P1X/315,DBDS20P1X/100,DBDS20G1X/400V,DBDS20G1X/315V,DBDS20K1X/25,DBDH15G1X/100V,DBDH10P1X/315,DBDH6P1X/50V,DBDH6K1X/400,DBDH6K1X/315,DBDS6P1X/100,DBDS20G1X/100V,DBDH10K1X/50,DBDS6P1X/50V,DBDS6K1X/200,DBDS10P1X/50,DBDS10G1X/315V,DBDA6G1X/400V,DBDH6G1X/315V,DBDS6P1X/315V,DBDS6P1X/200,DBDS30G1X/200V,DBDS30G1X/100,DBDH25G1X/100V,DBDS25G1X/315V,DBDS25G1X/315V,DBDA20G1X/50V,DBDA20 K1X/50V,DBDS20G1X/400,DBDS20K1X/50,DBDS15G1X/400,DBDA10P1X/25V,DBDH10P1X/50,DBDH10G1X/400,DBDS10P1X/630V,DBDS10G1X/25V,DBDS10K1X/25,DBDA8G1X/25V,DBDH8G1X/400,DBDH6P1X/100V,DBDS6P1X/50,DBDS6K1X/50,DBDH30G1X/25,DBDH30K1X/25,DBDS30G1X/50,DBDS30K1X/200,DBDA20P1X/100,DBDH20P1X/25, DBDS20P1X/315,DBDS20P1X/50,DBDS20K1X/50V,DBDH10G1X/100,DBDH10K1X/200, DBDS10G1X/630, DBDS10K1X/315, DBDA6K1X/100V,DBDH6G1X/400V, DBDS6G1X/25,DBDH10P1X/200V,DBDH10K1X/630V,DBDS10G1X/25,DBDS6G1X/400V,DBDS6G1X/400V,DBDS6K1X/400V,DBDS6K1X/50V,DBDS6K1X/50V,DBDS20K-10/100, DBDS20K-10/25,DBDS6K121X/100, DBDS10-P-1X/200 ,DBDS10K18/25 ,DBDH6G1/315, DBDH6G18/400/12,DBD15G10/315, DBDS6K1X/200, DBDS20P1X/315,Z2FS系列流量阀Z2FS10A3-3X, Z2FS10-5-3X ,Z2FS22-3X, Z2FS6-2-4X,Z2FS6B2-4X/2QV, Z2FS22-3X/S2,Z2FS10A3-3X/S2,Z2FS16-3X/S2,Z2FS22-3X/S ,Z2FS10,Z2FS10-5-3X/V,Z2FS6-2-43/1Q ,Z2FS6-2-4X/2QV ,Z2FS6-2-4X/2QV,Z2FS10-5-33/V ,Z2FS6-2-4X/V ,Z2FS10-5-3X ,Z2FS10-3X ,Z2FS22-3X/S2,Z2FS10-3X/,Z2FS6-2-4X/2QV, Z2FS16-31/S,Z2FS10-5-33/V, Z2FS6-2-4X/2QV, Z2FS10-5-3X/V, Z2FS10A5-3X/SV,Z2FS16-3X/S, Z2FS16-3X/S2, Z2FS22-3X/S2, Z2FS22-3X/S2/V, Z2FS6-2-4X/1Q, Z2FS6-2-4X/2QV ,Z2FS6-5-3X/V, Z2FS6-5-4X/1QV,Z2FS10-5-33/SV,Z2FS16-3X/S2V,Z2FS10-3-3X/V,Z2FS10-XX/,Z2FS10-5-33/V, Z2FS 6-2-43/1Q,阀 Z2FS22-3X/S2,Z2FS16-3X/S2, Z2FS22-31/S, Z2FS22-31/S2,Z2FS22-31/S, Z2FS22-31/S2, Z2FS10-20,DN6 Z2FS6-3X/V, Z2FS-2-4X/22QV, Z2FS16-3B/S2,Z2FS10-3X,Z2FS6-3X/V, Z2FS-2-4X/22QV, Z2FS6-2-44/2Q, Z2FS10-5-3X/V, Z2FS6-2-4X/2QV,Z2FS16-4X/S2, Z2FS 6-2-43/2QV, Z2FS6-4X/S2,Z2FS10-20/S2,Z2FS6-30/S2, Z2FS10-3X,Z2FS6-2-4X/2QV,Z2FS10-3X/S2 -,Z2FS6-30B, Z2FS6-30B, Z2FS16-3x/s2 -,Z2FS10-3X/, Z2FS6-30B,Z2FS16-3x/s2,Z2FS6 --- 720,Z2FS22-30B/S2,Z2FS16-30/S2 ,Z2FS10-20,Z2FS6-2-4X/2QV,Z2FS6-4X/2QV,力士乐手动阀4WMM10J31/,4WMM6E-5X/F ,4WMM10J-3X/,4WMM6D-53/F,4WMM6E-5X/F/B12V,4WMM6J-5X/ ,H-4WMM16E7X/F,H-4WMM16J7X/F,4WMM10J31/ ,4WMM16E7X/ ,4WMM10E3X/,4WMM6E6X/,4WMM6E-5X/F/B12V,4WMM6J5X, 4WMM6J53/V, 4WMM6C53/V ,4WMM6C53/Q-AG24/V ,4WMM6E-5X/F/B12V67827511, 4WMM6J5X ,4WMM6250/B10, 4WMM10E-3X,4WMM6J-5X/,4WMM6E-5X/F/B12V, 4WMM6E-5X/F/B12V,4WMM6J53/V, 4WMM6C53/V,4WMM6C53/Q-AG24/V,
力士乐电液换向阀4WEH22J7X/6EG24N9ETK4/B10,4WEH16J7X/6EG24N9K4/B08P4.5,4WEH22J76/6EG24N9ETS2K4/B10,4WEH22J7X/6EG24N9ETK4/B10 ,4WEH16H7X/6EG24N9ETK4/B10,4WEH16J72/6EG24N9ETS2K4/B10,H-4WEH25J66/6EG24N9ETK4,H-4WEH16J7X/6EG24N9ETK4 ,H-4WEH16D7X/6EG24N9ETRK4B15,4WEH16Y7X/GAG24NETK4, 4WEH25E50/6AW230 ,4WEH16E7X/6EG24N9ETK4,4WEH22-H7X/6EG24N9TS2K4 ,4WEH16E7X/6EG24N9ETK4,H-4WEH25G-6X/6SG24N9TK4,4WEH16E-7X/6SG24N9ETK4,4WEH16E-7X/6SG24N9ETK4/B10,H-4WEH25G-6X/6SG24N9TK4+,4WEH16E-6X/6AW110-50NEK4/B10, 4WEH16D-7X/6EG24N9EK4,44WEH16E-7X/6EG24N9EK4,44WEH16J-7X/6EG24N9ETS2K4/V, 4WEH22HD-7X/0F6EG24N9EK4/B10D3 -,4WEH25J-7X/6EG24ETS2Z4,H-4WEH25HD-6X/OF6EG24N9EK4/B12,H-4WEH25R-6X/6EG24N9ETK4V ,4WEH10E45/6AG24N9ETK4,4WEH32L6X/6AG24N9K4, 4WEH16E7X/6SG24 ,H-4WEH25G6/6SG24 -,4WEH16E61/6EG24NETZ5LB10,4WEH16D50/6AG24NETZ5L.24VDC,4WEH25J50/6AW220-50NZ4,4WEH16E7X/6EG24N9ETSK4 ,4WEH16D50/6AG24NETZ5,4WEH25J6X/6EG24N9ES2K31,4WEH16J7X/6EG24N9ES2K31,4WEH22JZX/6EG24N9ES2K4 ,4WEH16E6X ,H-4WEH25G6X ,4WEH10J45/6EW230N9ETSK4/B10,4WEH10D45/6EW230N9ETSK4/B10,4WEH16E7X/GEG24N9ETK4,4WEH22E7X/GEG24N9ETKS,4WEH16E6X,4WEH16G50/6AG24NESZ4,4WEH25J66/6EG24N9ETS2K4,4WEH16E7X/6EG24N9TK4+Z4,H-4WEH25G6X/6EG24N9TK4+Z4,4WEH16J62/EG24N9K4/V,4WEH16E7X/6HG24N9ETK4/B10,H-4WEH25G6X/6SG24N9TK4 ,4WEH25J66/6EG24N9ETS2K4 ,4WEH10D4X/6EG24N9TK4B10 ,4WEH16E72/6EW100N9TS2DJL ,4WEH16JB/6AG24N9EK4, 4WEH16E7X/6EG24N9ETK4,4WEH16E72/6EW100N9TS2DJL,Z4WEH10E63-50/4KE24N9ETK4,4WEH16E72/6EW100N9TS2DJL,4WEH16E7X/6EG24N9ETK4,4WEH25E50/6AW230 ,4WEH16E72/6EW100N9TS2DJL,4WEH16E72/6HG24N9EK4,H-4WEH25G67/6HG24N9TK4,,4WEH16E72/6EW100N9TS2DJL,4WEH16G,4WEH10J7X/OF6AW230N9ETK4QNAG24, 4WEH10Y7X/OF6AW230N9ETKOMAG24/,4WEH16E7X/6EG24N9ETK4 ,4WEH16J-50/6AG24 ,4WEH10J3X/EG24NZ5L,4WEH16J50/AG24NETZ5L,4WEH16E 7X/6SG24N9ETK4/ ,H-4WEH25G6X/6SG24N9TK4 -,4WEH16E7X/6HG24N9ETK4/B10 ,H-4WEH25G6X/6SG24N9TK4 ,4WEH16E7X/6EG24N9ETK4, 4WEH16J-50/6AG24, 4WEH10J3X/EG24NZ5L,4WEH16J50/AG24NETZ5L, 4WEH16E 7X/6SG24N9ETK4/,H-4WEH25G6X/6SG24N9TK4 ,,4WEH16J61/CG24NETZ5L,4WEH16E7X/6SG24N9ETK4, H-4WEH25G6X/6SG24N9TK4 ,H4WEH16E7X6EG24NET/B15P4.5 ,4WEH 22 D7X/6EG24N9ETK4 ,H-4WEH16E-7X/6AG24NTK4+57292 ,H-4WEH25G-6X/6AG24NTK4+57292,
力士乐单向节流阀DRVP10-10/2 ,DR20-5-52/200YM,ZDR10DP1-5X/150YM ,ZDR6DP1-5X/210Y,ZDR6DP2-4X/150YM ,DR20-5-5X/100Y,ZDR10VP5-3X/200YM, ZDR6DP1-4X/210YM,ZDR10DA1-5X/150Y,ZDR10DP1-5X/150YM,ZDR6DA2-4X/150Y,ZDR6DP1-4X/150YM,ZDR6DP2-4X/150YM ,DR20-5-5X/200YM,ZDR6DP0-45/40YMVW80 ,ZDR6DP2-5X/315YM ,ZDR6DA2-4X/150Y ,DR10-5-52/100YM -,ZDR 10DP1-54/150YM ,DR20-4-5X/315Y,DR10DP2-4X/210YM ,DR10-5-5X/200YM ,DR20-5-5X/315YM, ZDR6DA1-4X/75Y,DR10-1-30B/315YM ,DR20-5-5X/315YM ,ZDR6DP0-5/40YMVW80,ZDR6DP2-5X/315YM,ZDR6DA2-4X/150Y ,DR10-5-52/100YM,3DREM10P5-6X/100Y/OOM ,3DREM10P6X/315YG24K4V-1,FDR5DP1/55YS037,FDR5DP1-1X/55YS037,DR10-4-43/100Y,DR20-5-5X/200YMV, DR30-5-5X/200YV, DR10-4-43/100Y,DR20-5-5X/200YMV,DR30-5-5X/200YV,ZDR10DA2-5X/210YV, ZDR10DP1-5X/150YM,ZDR10-DP2-52/75Y,ZDR10DP2-5X/150YM,ZDR10DP2-5X/210YMV,ZDR10VP5-3X/200YMV, ZDR10VP5-3X/315MV, ZDR10VP6-3X/200YV, ZDR6DA2-4X/150YV,ZDR6DP1-4X/75YM,ZDR6DP2-4X/150YM, ZDR6DP2-4X/210YM, ZDR6DP2-4X/210YM,DRV10-01-X/0, DR6DP2-ZDR6DA1/210Y ,DRVP10-10/2 DRVP30 ,RVP20 ,RVP30.10 ,RVP16-10 ,DRVP30, RVP20, RVP30.10,ZDB溢流阀ZDB6GVB2-4X ,ZDB6GVB2-4X/200V ,ZDB6VA1-4X/200V, ZDB10VA1-4X/200V, ZDB10VA1, ZDB10VA1-4X/200V,ZDB10VP2-41/200V ,ZDB10VC2-4X/200V, ZDB10VB2-4X/200V, ZDB10VP2-41/200V ,ZDB10VA1-4X/200V,ZDB10VA1-4X/200V,ZDB6VB-3-40B/100, ZDB10VB2-41/50V ,ZDB10VC2-4X/200V, ZDB10VC2-4X/200V,ZDB6VP2-4X/100V,ZDB6VP2-4X/315V,ZDB1OVA2-41/50P30V, ZDB10B1-4X/200V, Z1S6T1-3X/V, Z1S10T1-3X,Z1S10T1-3X ,Z1S10T1-3X/V, Z1S16F1-1X/V, Z1S16P1-3X/V, Z1S10T2-30B/,Z1S10P1 ,力士乐SV系列单向阀SVLD546P20S, SV30PA2-30,SV30PA1-4X ,SV30PA4-4X,SV20PA3-4X ,SVS-3-1/8 ,SV10GB1-4X ,V10PA1-4X,SV20GA1-4X/V,Z2FS10A5-3X/SV,Z2FS10-5-33/SV, SV30PA3-30 ,SVS-3-1/8 ,SV10-PB-1-42 ,SV10PB1-42 ,SV30PA1-4X ,SV20PA31-4X, SV16PA2-3X ,SV30PA2-30 ,SV10-PB-1-42, SV10PA4-4X ,SV20PA3-4X ,SV20PA3-4X,SV10GA1/2 ,SV20PA1/2 -,SV20PA4-4X/,
德国力士乐 三位四通比例阀 4WEZ10W50-3X/GA24NEZ4/D2M-S066,4WEZ10W50-3X/GA24NEZ4/D2M-S066,
力士乐M-3SE比例阀M-3SED6CK-1/350CG24N9K4/V ,M-3SED6CK-13/315CG24N9K4/V, M-3SED6UK-10/350CG205N9Z4,M-CK1X/350CC24N9K4
力士乐HED压力继电器HED80H1×1200K14A ,HED40P10/350S,HED50P.20/210L24,HED80A1X/350K14,HED80P1X/50K14S,HED80P-1X/315+Z15L24, HED8-OP-1X/200-K14-S ,HED8-OP-1X/200-K14-S, HED40P10/350S,HED80A1X/350K14,HED50P.20/210L24,HED80H1×1200K14A ,HED40P10/350S,HED50P.20/210L24,
德国SERA(赛诺)计量泵德国SERA(赛诺)计量泵
德国赛诺(sera)公司位于德国黑森州的伊门豪森,成立于1945年.在德国国内有12家分公司,在世界各地30多个国家设有代理或代表处。产品有气动隔膜泵、电磁隔膜泵、机械隔膜泵、活塞隔膜泵、加药装置及隔膜压缩机。 多样化的设计可解决各种计量技术上的问题。这充分体现于sera根据客户的技术要求所提供的各种不同的泵和加药系统的设计上。产品满足经济性需要,且符合环保要求。
德国Sera(赛诺)计量泵
.运作时高度安全,计量精确,化学药品在使用过程中的经济性和环保.针对介质接触表面的特性选择高质量的材料,泵的使用寿命.多样化的设计可解决各种计量技术上的问题.这充分体现于Sera根据客户的技术要求所提供的各种不同的泵和加药系统的设计上.Sera的产品满足经济性需要,且符合环保要求
INA供应德国INA月牙轴承
陈晓 壹叁捌柒壹壹捌贰捌玖叁
我司专业销售工程机械(混凝土机械、路桥、路面机械)、工业设备、冶金机械、大型矿山机械、陶瓷、船舶等液压泵、马达、各种减速机总成及零配件并维修,大小型设备液压系统设计、生产改造及维修,引进国外技术人才,并备有进口液压系统测试台,能针对各种疑难杂症进行调试修复,并代理销售力士乐、萨澳、川崎原装进口液压泵、马达及零配件,品种齐全,质优物廉。
- 供应力士乐A11VO75总成及配件,配件有:柱塞,缸体,配油盘,回程盘,球铰,摇摆压板,摇摆,油封,月牙轴承,月牙轴承座,传动轴,大轴承,小轴承等均有现货。
- 力士乐双联齿轮泵
HCS71902C.T.P4S.UL轴承德国进口轴承HCS71902C.T.P4S.UL进口轴承
德国进口轴承HCS71902C.T.P4S.UL进口轴承 CC5——圆柱滚子轴承(不可互换)径向游隙,比CC4游隙大。MC1——小型,微型球轴承径向游隙,比MC2游隙小。MC2——小型,微型球轴承径向游隙,比MC3游隙小。MC3——小型,微型球轴承径向游隙标准游隙。
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德国cellast单细胞力学加载仪
背景: 单细胞水平的机械力特性表征,可以有效阐明细胞的功能和状态,揭示细胞的单体差异性,对于细胞的分化和病理研究,以及疾病的早期临床诊断和治疗具有非常重要的意义。 该系统基于微流控芯片的方式更适合单细胞样本的微环境精确控制、高通量定向操纵及多参数非特异性检测。 简介: 该单细胞高通量牵张与力学特性测试分析系统,是世界台用来高通量测量、分析单个悬浮细胞形变的设备。用来可视化研究讨论细胞力学性质与其功能之间的关系 该系统可以安装在任何相位差显微镜上的模块。温度稳定和激光安全。 
单个细胞加力模式如下图:由两束细胞无损激光夹持细胞进行牵拉或挤压,进而使单个细胞受到牵张拉伸或压缩力刺激。
系统亮点特性:
1 )可大量表征单细胞机械力特性、操作简便、样品消耗量小 该系统的微流控芯片具有与细胞直径良好相符性的微纳米级腔道,并能实现对微流体的精确控制,使其尤其适合单细胞机械特性研究分析,该微流控的高通量技术便于大量表征单细胞机械力特性、操作简便、样品消耗量小、集成和微型化程度高等优点,且在分析过程中单细胞悬浮高速流经检测区域,该连续流动态检测的特性极大提高了系统的通量。 2)高速对单个细胞进行形变,并进行机械特性高速表征,单细胞高通量流变 利用两素未聚焦光进行单细胞形变,并通过图形化微柱基地表征细胞的力特性,高速有效分析单细胞水平的机械特性, 高达300个细胞/小时. 3)非机械接触、无标记进行细胞捕捉和拉伸,确保细胞安全与细胞损伤***小化(Contact-free cell deformation)利用光延伸器技术测试细胞机械特性能时,在非机械接触情况下细胞进行捕捉和拉伸,且不需要对激光进行聚焦,能实现细胞损伤***小化。优于AFM(原子力显微镜)和光镊 4)将光延伸器安全性与微流控高通量完美相结合,细胞机械特性测试分析安全而且高效 采用2个微流道来输送细胞,使两条光纤垂直分布于通道两侧并严格对准? ,单细胞随流体进入检测区域时,首先采用功率较低的光速捕获细胞,然后增加光速的功率使细胞发生形变。通过对细胞变形能力的分析,不仅能区分病变细胞和正常细胞,而且可以用于辨别转型特性和非转移特性的癌细胞。 5)自动化测量单细胞力属性和成像记录细胞形变记录 对应于用户定义的拉伸模式,细胞被自动传送到测量区域由CellStretcher模块控制所有组件和自动测量细胞;细胞形变由系统CCD相机自动记录,并由CellEvaluator自动提取记录显微图像形变数据,CellReporter可视化统计分析表征参数。在光学拉伸加载运行实验中,科研学者可专注于阐述实验结果 6)良好温控微环境罩
中国代理服务商:北京思睿维科技有限公司 马金龙 18601970048
Publications
RS ZELLTECHNIK BROCHURES
The Optical Stretcher
OPTICAL STRETCHER TECHNOLOGY
Lincoln, B., Schinkinger, S., Travis, K., Wottawah, F., Ebert, S., Sauer, F., Guck, J., 2007. Reconfigurable microfluidic integration of a dual-beam laser trap with biomedical applications. Biomed. Microdevices 9, 703–710. doi:10.1007/s10544-007-9079-xEbert, S., Travis, K., Lincoln, B., Guck, J., 2007. Fluorescence ratio thermometry in a microfluidic dual-beam laser trap. Opt. Express 15, 15493–15499. doi:10.1364/OE.15.015493Jensen-McMullin, C., Lee, H.P., Lyons, E.R.L., 2005. Demonstration of trapping, motion control, sensing and fluorescence detection of polystyrene beads in a multi-fiber optical trap. Opt. Express 13, 2634–2642. doi:10.1364/OPEX.13.002634Wottawah, F., Schinkinger, S., Lincoln, B., Ananthakrishnan, R., Romeyke, M., Guck, J., K?s, J., 2005. Optical Rheology of Biological Cells. Phys. Rev. Lett. 94, 098103. doi:10.1103/PhysRevLett.94.098103Lincoln, B., Erickson, H.M., Schinkinger, S., Wottawah, F., Mitchell, D., Ulvick, S., Bilby, C., Guck, J., 2004. Deformability-based flow cytometry.Cytometry A 59A, 203–209. doi:10.1002/cyto.a.20050
THEORETICAL MODELS
Ananthakrishnan, R., Guck, J., Wottawah, F., Schinkinger, S., Lincoln, B., Romeyke, M., Kas, J., 2005. Modelling the structural response of an eukaryotic cell in the optical stretcher. Curr. Sci. 88.B. Bareil, P., Sheng, Y., Chiou, A., 2006. Local scattering stress distribution on surface of a spherical cell in optical stretcher. Opt. Express 14, 12503–12509. doi:10.1364/OE.14.012503 Bareil, P.B., Sheng, Y., Chen, Y.-Q., Chiou, A., 2007. Calculation of spherical red blood cell deformation in a dual-beam optical stretcher. Opt. Express 15, 16029–16034. doi:10.1364/OE.15.016029 Boyde, L., Ekpenyong, A., Whyte, G., Guck, J., 2012. Comparison of stresses on homogeneous spheroids in the optical stretcher computed with geometrical optics and generalized Lorenz–Mie theory. Appl. Opt. 51, 7934–7944. doi:10.1364/AO.51.007934Ekpenyong, A.E., Posey, C.L., Chaput, J.L., Burkart, A.K., Marquardt, M.M., Smith, T.J., Nichols, M.G., 2009. Determination of cell elasticity through hybrid ray optics and continuum mechanics modeling of cell deformation in the optical stretcher. Appl. Opt. 48, 6344–6354. doi:10.1364/AO.48.006344Teo, S.-K., Goryachev, A.B., Parker, K.H., Chiam, K.-H., 2010. Cellular deformation and intracellular stress propagation during optical stretching.Phys. Rev. E 81, 051924. doi:10.1103/PhysRevE.81.051924
CANCER RESEARCH AND DIAGNOSTICS
Kastl, L., Budde, B., Isbach, M., Rommel, C., Kemper, B., Schnekenburger, J., 2015. Optomechanical properties of cancer cells revealed by light-induced deformation and quantitative phase microscopy. pp. 952908–952908–6. doi:10.1117/12.2184764Martin, M., Müller, K., Cadenas, C., Hermes, M., Zink, M., Hengstler, J.G., K?s, J.A., 2012. ERBB2 overexpression triggers transient high mechanoactivity of breast tumor cells. Cytoskeleton 69, 267–277. doi:10.1002/cm.21023Fritsch, A., H?ckel, M., Kiessling, T., Nnetu, K.D., Wetzel, F., Zink, M., K?s, J.A., 2010. Are biomechanical changes necessary for tumour progression? Nat. Phys. 6, 730–732. doi:10.1038/nphys1800Brunner, C., Niendorf, A., K?s, J.A., 2009. Passive and active single-cell biomechanics: a new perspective in cancer diagnosis. Soft Matter 5, 2171–2178. doi:10.1039/B807545JRemmerbach, T.W., Wottawah, F., Dietrich, J., Lincoln, B., Wittekind, C., Guck, J., 2009. Oral Cancer Diagnosis by Mechanical Phenotyping. Cancer Res. 69, 1728–1732. doi:10.1158/0008-5472.CAN-08-4073Martin, M., Mueller, K., Wottawah, F., Schinkinger, S., Lincoln, B., Romeyke, M., K?s, J.A., 2006. Feeling with light for cancer. p. 60800P–60800P–10. doi:10.1117/12.637899Guck, J., Schinkinger, S., Lincoln, B., Wottawah, F., Ebert, S., Romeyke, M., Lenz, D., Erickson, H.M., Ananthakrishnan, R., Mitchell, D., K?s, J., Ulvick, S., Bilby, C., 2005. Optical Deformability as an Inherent Cell Marker for Testing Malignant Transformation and Metastatic Competence. Biophys. J. 88, 3689–3698. doi:10.1529/biophysj.104.045476
STEM CELL RESEARCH
Ekpenyong, A.E., Whyte, G., Chalut, K., Pagliara, S., Lautenschlaeger, F., Fiddler, C., Paschke, S., Keyser, U.F., Chilvers, E.R., Guck, J., 2012.Viscoelastic Properties of Differentiating Blood Cells Are Fate- and Function-Dependent. Plos One 7, e45237. doi:10.1371/journal.pone.0045237Galle, J., Bader, A., Hepp, P., Grill, W., Fuchs, B., Kas, J.A., Krinner, A., MarquaB, B., Muller, K., Schiller, J., Schulz, R.M., von Buttlar, M., von der Burg, E., Zscharnack, M., Loffler, M., 2010. Mesenchymal Stem Cells in Cartilage Repair: State of the Art and Methods to monitor Cell Growth, Differentiation and Cartilage Regeneration. Curr. Med. Chem. 17, 2274–2291. doi:10.2174/092986710791331095Maloney, J.M., Nikova, D., Lautenschlager, F., Clarke, E., Langer, R., Guck, J., Van Vliet, K.J., 2010. Mesenchymal Stem Cell Mechanics from the Attached to the Suspended State. Biophys. J. 99, 2479–2487. doi:10.1016/j.bpj.2010.08.052Lautenschl?ger, F., Paschke, S., Schinkinger, S., Bruel, A., Beil, M., Guck, J., 2009. The regulatory role of cell mechanics for migration of differentiating myeloid cells. Proc. Natl. Acad. Sci. 106, 15696–15701 doi:10.1073/pnas.0811261106
IMMUNE SYSTEM
Man, S.M., Ekpenyong, A., Tourlomousis, P., Achouri, S., Cammarota, E., Hughes, K., Rizzo, A., Ng, G., Wright, J.A., Cicuta, P., Guck, J.R., Bryant, C.E., 2014. Actin polymerization as a key innate immune effector mechanism to control Salmonella infection. Proc. Natl. Acad. Sci. 201419925 doi:10.1073/pnas.1419925111
BASIC RESEARCH
Schmidt, B.U.S., Kie?ling, T.R., Warmt, E., Fritsch, A.W., Stange, R., K?s, J.A., 2015. Complex thermorheology of living cells. New J. Phys. 17, 073010. doi:10.1088/1367-2630/17/7/073010Chan, C.J., Ekpenyong, A.E., Golfier, S., Li, W., Chalut, K.J., Otto, O., Elgeti, J., Guck, J., Lautenschl?ger, F., 2015. Myosin II Activity Softens Cells in Suspension. Biophys. J. 108, 1856–1869. doi:10.1016/j.bpj.2015.03.009Gladilin, E., Gonzalez, P., Eils, R., 2014. Dissecting the contribution of actin and vimentin intermediate filaments to mechanical phenotype of suspended cells using high-throughput deformability measurements and computational modeling. J. Biomech. 47, 2598–2605. doi:10.1016/j.jbiomech.2014.05.020Maloney, J.M., Vliet, K.J.V., 2014. Chemoenvironmental modulators of fluidity in the suspended biological cell. Soft Matter. doi:10.1039/C4SM00743CWarmt, E., Kie?ling, T.R., Stange, R., Fritsch, A.W., Zink, M., K?s, J.A., 2014. Thermal instability of cell nuclei. New J. Phys. 16, 073009. doi:10.1088/1367-2630/16/7/073009Gyger, M., Stange, R., Kiessling, T.R., Fritsch, A., Kostelnik, K.B., Beck-Sickinger, A.G., Zink, M., Kaes, J.A., 2014. Active contractions in single suspended epithelial cells. Eur. Biophys. J. Biophys. Lett. 43, 11–23. doi:10.1007/s00249-013-0935-8Seltmann, K., Fritsch, A.W., K?s, J.A., Magin, T.M., 2013. Keratins significantly contribute to cell stiffness and impact invasive behavior. Proc. Natl. Acad. Sci. 201310493. doi:10.1073/pnas.1310493110Maloney, J.M., Lehnhardt, E., Long, A.F., Van Vliet, K.J., 2013. Mechanical fluidity of fully suspended biological cells. Biophys. J. 105, 1767–1777. doi:10.1016/j.bpj.2013.08.040Kie?ling, T.R., Stange, R., K?s, J.A., Fritsch, A.W., 2013. Thermorheology of living cells—impact of temperature variations on cell mechanics. New J. Phys. 15, 045026. doi:10.1088/1367-2630/15/4/045026Kie?ling, T.R., Herrera, M., Nnetu, K.D., Balzer, E.M., Girvan, M., Fritsch, A.W., Martin, S.S., K?s, J.A., Losert, W., 2013. Analysis of multiple physical parameters for mechanical phenotyping of living cells. Eur. Biophys. J. 42, 383–394. doi:10.1007/s00249-013-0888-yPaschke, S., Weidner, A.F., Paust, T., Marti, O., Beil, M., Ben-Chetrit, E., 2013. Technical advance: Inhibition of neutrophil chemotaxis by colchicine is modulated through viscoelastic properties of subcellular compartments. J. Leukoc. Biol. 94, 1091–1096. doi:10.1189/jlb.1012510Chalut, K.J., H?pfler, M., Lautenschl?ger, F., Boyde, L., Chan, C.J., Ekpenyong, A., Martinez-Arias, A., Guck, J., 2012. Chromatin decondensation and nuclear softening accompany Nanog downregulation in embryonic stem cells. Biophys. J. 103, 2060–2070. doi:10.1016/j.bpj.2012.10.015Matthews, H.K., Delabre, U., Rohn, J.L., Guck, J., Kunda, P., Baum, B., 2012. Changes in Ect2 localization couple actomyosin-dependent cell shape changes to mitotic progression. Dev. Cell 23, 371–383. doi:10.1016/j.devcel.2012.06.003Mauritz, J.M.A., Esposito, A., Tiffert, T., Skepper, J.N., Warley, A., Yoon, Y.-Z., Cicuta, P., Lew, V.L., Guck, J.R., Kaminski, C.F., 2010. Biophotonic techniques for the study of malaria-infected red blood cells. Med. Biol. Eng. Comput. 48, 1055–1063. doi:10.1007/s11517-010-0668-0Rusciano, G., 2010. Experimental analysis of Hb oxy–deoxy transition in single optically stretched red blood cells. Phys. Med. 26, 233–239. doi:10.1016/j.ejmp.2010.02.001
AGING PROCESSES
Schulze, C., Wetzel, F., Kueper, T., Malsen, A., Muhr, G., Jaspers, S., Blatt, T., Wittern, K.-P., Wenck, H., K?s, J.A., 2010. Stiffening of Human Skin Fibroblasts with Age. Biophys. J. 99, 2434–2442. doi:10.1016/j.bpj.2010.08.026
VESICLES
Delabre, U., Feld, K., Crespo, E., Whyte, G., Sykes, C., Seifert, U., Guck, J., 2015. Deformation of phospholipid vesicles in an optical stretcher. Soft Matter. doi:10.1039/C5SM00562KSolmaz, M.E., Sankhagowit, S., Biswas, R., Mejia, C.A., Povinelli, M.L., Malmstadt, N., 2013. Optical stretching as a tool to investigate the mechanical properties of lipid bilayers. Rsc Adv. 3, 16632–16638. doi:10.1039/c3ra42510j Solmaz, M.E., Biswas, R., Sankhagowit, S., Thompson, J.R., Mejia, C.A., Malmstadt, N., Povinelli, M.L., 2012. Optical stretching of giant unilamellar vesicles with an integrated dual-beam optical trap. Biomed. Opt. Express 3, 2419–2427. doi:10.1364/BOE.3.002419
TECHNICAL ADVANCES
Grosser, S., Fritsch, A.W., Kie?ling, T.R., Stange, R., K?s, J.A., 2015. The lensing effect of trapped particles in a dual-beam optical trap. Opt. Express 23, 5221–5235. doi:10.1364/OE.23.005221Bellini, N., Bragheri, F., Cristiani, I., Guck, J., Osellame, R., Whyte, G., 2012. Validation and perspectives of a femtosecond laser fabricated monolithic optical stretcher. Biomed. Opt. Express 3, 2658–2668. doi:10.1364/BOE.3.002658 Bellini, N., Vishnubhatla, K.C., Bragheri, F., Ferrara, L., Minzioni, P., Ramponi, R., Cristiani, I., Osellame, R., 2010. Femtosecond laser fabricated monolithic chip for optical trapping and stretching of single cells. Opt. Express 18, 4679–4688. doi:10.1364/OE.18.004679中国代理服务商:北京思睿维科技有限公司 马金龙 18601970048
UV-150能量计能量仪深圳总代德国原产UV-150能量计能量仪(原装进口,假一罚十)
德国原装UV150能量计 UV-INT150能量仪 德国UV150紫外线能量计
( UV-Integrator150能量计 产地:德国原装UV150能量计)
德国UV150紫外线能量计是用于测量曝光装置的UV能量的一种仪器,UV150测量仪的主感器在测量仪的背面,测量范围为250~410纳米,测量时可直接显示于UV能量计正面的显示屏上读出(单位:毫焦耳/平方厘米),该UV能量计的电源为3.6伏特的锂电池,该电池由于使用了特别的能源节省线路,该电池可持续大约10000小时。
德国UV150能量计 技术数据:
尺寸:直径90mm 高12mm
重量:约150g 适用设备:UV紫外线干燥机、曝光机
测量范围:0-5000mW/cm2
能量显示:LCD 0-999999mj/cm2
电源: 锂电池3.6V UV
测量范围: 250-410nm(光谱图波长)
耗电量: 约10000小时(Lithiwn锂电池)
工作温度(℃): 0~70℃ 本UV能量计在输送带上耐温110℃不超过10秒
德国原装UV-INT150紫外线能量计!德国原厂UV150能量计!
UV-150能量计使用/操作
a. 打开ON开关,则LCD(显示屏)是显示为零。
b. 将UV能量计放置于曝光UV灯源附近,以其背面对准灯源(UV能量计的能量感受器在背面).
c. 直到UV能量计的显示屏上有测量显示,例如800毫焦耳/平方厘米。(800mj/cm2)
d. 将显示屏的值记录或作为品质控制与实验参数,关掉UV能量计开关(OFF)。
PS1德国马尔便携式粗糙度仪一级经销商
1.它的最大测量范围为 350 µm(0.014 in)(-200 µm 至 +150 µm)(-0.008 in 至+0.006 in)。
详细介绍
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德国马尔原装进口
| 德国马尔便携式粗糙度仪/MarSurf PS1
MarSurf PS1粗糙度仪的技术参数:
MarSurf PS1.粗糙度仪套件介绍 MarSurf PS1为一完整的套件设计,配套的挂包设计,使您可以随时随地携带自己的表面糙度测量仪器.快速可靠的现场测量使您在生产过程或来货检测中得到所需的质量要求. PS1粗糙度仪套件包含 *MarSurf Ps1基本单元 *驱动器单元 *1个符合标准设计规定的标准传感器 *内置电池 *保护套设计的集成粗糙度标准 *高度调节附件 *传感器保护装置 *充电器/电源适配器 *操作说明 *带有肩带和手提包 *USB连接电缆线 |
23060CA轴承23060CA轴承FAG德国进口轴承
23060CA轴承23060CA轴承23060CA轴承23060CA轴承 调心滚子轴承具有两列滚子,主要承受径一载荷,同时也能承受任一方向的轴向载荷。有高的径向载荷能力,特别适用于重载或振动载荷下工作,但不能承受纯轴向载荷。该类轴承外圈滚道是球面形,故其调心性能良好,能补偿同轴度误差。
调心滚子轴承有两列对称型球面滚子,外圈有一条共用的球面滚道,内圈有两条与轴承轴线倾斜一角度的滚道,具有良好的调心性能,当轴受力弯曲或安装不同心时轴承仍可正常使用,调心性随轴承尺寸系列不同而异,一般所允许的调心角度为1~2.5度 ,该类型轴承的负荷能力较大,除能承受径向负荷外轴承还能承受双向作用的轴向负荷,具有较好的抗冲击能力,一般来说调心滚子轴承所允许的工作转速较低。
主要适用的保持架:冲压钢板保持架(后缀E)、玻璃纤维增强型聚酰胺66保持架(后缀TVPB)、机加工黄铜实体保持架(后缀M)、振动场合冲压钢板保持架(后缀JPA) 主要用途:造纸机械、减速装置、铁路车辆车轴、轧钢机齿轮箱座、轧钢机辊道子、破碎机、振动筛、印刷机械、木工机械、各类产业用减速机、立式带座调心轴承。
原装进口德国ALRE AFHP100(G9040160) 压差开关 电子元器件
产品介绍:德国ALRE 温度开关德国ALRE 温控器德国ALRE 传感器德国ALRE 湿度传感器德国ALRE 压差开关产品型号:德国ALRE JDLEEE德国ALRE KR 85.406-2(TW/TW) 15 (8)A, 24 250V德国ALRE AFP100(G9040010)德国ALRE AFHP100(G9040160)德国ALRE FF-K1(G8000269)德国ALRE 1KF1P100/300德国ALRE DF300-UGT3(G8000277)德国ALRE LR80.318德国ALRE JDL-11 Art-Nr:130-0574 Lagerplatz:L09-115德国ALRE JTF-1 -10--12°C 230V50HZ 1W德国ALRE JET - 130XF 40-100°C德 国ALRE type JTF-1; setting range: -16 ... +12 ~C; protection class IP 40 single-pole double-throw contact; capillary lengzh: 6.000 mm; material Cu wilh 1 set (6 pieces) mounting bracket type JZ-O5/6德国 ALRE type JET-16 XN-F; setting range: 40 - 100 ~C; protection class IP 65 single-pole double-throw contact; capillary length: 1.500 mm; material Cu with capillary holder SW 200德国ALRE JTF-22德国ALRE DF300-UGT3德国ALRE AFHP100德国ALRE FF-K1 0-10V
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