NGIP seies Construction/Parts List Auto Switch Type . . . .. 6 Dimensions N o s e M o u n V F l a n g e M o u n t . . . . . . . . . 7 4 Construction/Parts List . . .
T N E K I ETL LISTED CONFORMS TO M C AC EXT.SENSOR CERTIFIED TO UL STD 60601-1 US C D L I E S T 3054524 Circulating fluid outlet Rc1/4 CAN/CSA STD C22.2 NO.601.1 THERMO-CON HEC002-A5B-F MODEL No.
The ZSE2 series is a compact, pressure switch (for vacuum pressure) and can be integrated with ZX or ZR vacuum systems. The ZSE2 series pressure switch has a quick response time of 10mS and the plug connector option makes wiring easy and simple. VACUUM SWITCH, ZSE30, ZSE30A. 3 SCREEN HI PRECISION DIG PRESS SWITCH. 71.00000 lb. N63.
The ZSE2 series is a compact, pressure switch (for vacuum pressure) and can be integrated with ZX or ZR vacuum systems. The ZSE2 series pressure switch has a quick response time of 10mS and the plug connector option makes wiring easy and simple., 3 SCREEN HI PRECISION DIG PRESS SWITCH, VACUUM SWITCH, ZSE30, ZSE30A, N63, 71.00000 lb
The ZSE2 series is a compact, pressure switch (for vacuum pressure) and can be integrated with ZX or ZR vacuum systems. The ZSE2 series pressure switch has a quick response time of 10mS and the plug connector option makes wiring easy and simple., 3 SCREEN HI PRECISION DIG PRESS SWITCH, VACUUM SWITCH, ZSE30, ZSE30A, N63, 71.00000 lb
Load applied perpendicularly to the rod (Received by guide) Load Operating pressure Graph 2 0.3MPa~ Example 0.4MPa~ Graph 3 Load weight: m=50kg Travel distance: st=500mm Positioning time: t=2s Load: Graph 4 0.5MPa~ Vertically downwards = Load in extending direction of the rod Load applied in extending direction of the rod Load applied in retracting direction of the rod Operating pressure:
Load applied perpendicularly to the rod (Received by guide) Load Operating pressure Graph 2 0.3MPa~ Example 0.4MPa~ Graph 3 Load weight: m=50kg Travel distance: st=500mm Positioning time: t=2s Load: Graph 4 0.5MPa~ Vertically downwards = Load in extending direction of the rod Load applied in extending direction of the rod Load applied in retracting direction of the rod Operating pressure:
Load applied perpendicularly to the rod (Received by guide) Load Operating pressure Graph 2 0.3MPa~ Example 0.4MPa~ Graph 3 Load weight: m=50kg Travel distance: st=500mm Positioning time: t=2s Load: Graph 4 0.5MPa~ Vertically downwards = Load in extending direction of the rod Load applied in extending direction of the rod Load applied in retracting direction of the rod Operating pressure:
Moment (M) Nm 14.5 16 19.5 28 Max. Moment (M) = Length (L) x Load (F) If a commercially available switching power supply is used, be sure to connect the frame ground (FG) terminal to ground. Do not drop, hit or apply excessive shock to the product. Otherwise damage to the internal components may result, causing malfunction.
5 u q y e t !2 w i A CJ1 CJP CJ2 A Cylinder tube sectional view A-A !0 o CM2 CG1 Component Parts MB No. q w e r t y u i o !0 !1 No.
Kg) 100 70 50 30 20 10 7 200 250 300 350 400 450 500 550 600 V(m/s) Example: Load limit at rod end when air cylinder 50 is actuated with max. actuating speed 325mm/s.
DC12~24V10% DC12~24V10% DC(+) DC(-) 9 / / 10 () 11 /5 m / 12 10~15 10 "-M" (kPaMPa) ( ) "-M" 13 SI kPa,MPa -47No.PS-OMM0002CN-F No. 14 15 16 () 17 () ( ) () / -48No.PS-OMM0002CN-F 80mA 10 1 1dight 1 -49No.PS-OMM0002CN-F ISE80() ISE80H() ZSE80() ZSE80F() -0.11MPa -0.12MPa 0-101kPa -100100kPa -0.1051.1MPa -0.1052.2MPa 10-111kPa -110110kPa 2 MPa 4 MPa 500 kPa 0.001 MPa
The kinetic energy of load can be found using the following formula. 20 10 5 V M M 2 V 2 100 300 1000 2000 500 Ek = Ek: Kinetic energy (J) M: Weight of load (kg) V: Piston speed (m/s) Maximum drive speed (mm/s) Example) Load limit at rod end when air cylinder 63 is actuated with max. actuating speed 500 mm/s. at a maximum drive speed of 500 mm/s.
, PLC Yes Grommet 24 V IC circuit Diagnostic indication (2-color display) 5 V, 12 V 12 V Lead wire length symbols: 0.5 m Nil (Example) M9NW 1 m M (Example) M9NWM 3 m L (Example) M9NWL 5 m Z (Example) M9NWZ Solid state auto switches marked with are produced upon receipt of order.
Vacuum Regulator Series IRV10/20 RoHS How to Order Standard connections IRV 20 C08 Accessory w Body size 10 20 Max. flow 140 l/min (ANR) Max. flow 240 l/min (ANR) None Note 1) Nil With pressure gauge Note 2) Note 3) (IRV10: With GZ33-K-01, IRV20: With GZ43-K-01) G Note 3) ZN ZP ZA ZB With ZSE30A-01-N-ML With ZSE30A-01-P-ML With ZSE30A-01-A-ML With ZSE30A-01-B-ML NPN open collector 1 output
Detection nozzle: 1.5 Detection nozzle piping: F type 4 x 2.5 tube 1 m, 3 m, 5 m/G, H type 6 x 4 tube 1 m, 3 m, 5 m Supply pressure: 200 kPa Test conditions ISA3-F ISA3-G 300 60 3 m 1 m 250 50 5 m 1 m 5 m Displayed value Displayed value 200 40 3 m 150 30 100 20 50 10 0 0 0.3 0.25 0.2 0.15 0.1 0.05 0 0.06 0.05 0.04 0.03 0.02 0.01 0 Actual distance [mm] Actual distance [mm] ISA3-H 500 450 3
T-nuts (weight 10.0g) Dedicated communication cable (IBM PC/AT compatible computer) M Model LC1-1-RC M Model 17.5 LC1-1-N3 M3 x 0.5 Cable length 02 2m 04 4m 03 3m 05 5m LC1-1-N5 M5 x 0.8 18 7.5 PC Controller T-brackets Model LC1-1-L5 (weight 16.0g) Model LC1-1-L3 (weight 15.5g) Cable length: 2 to 5m M5 M3 17.5 17.5 11 Dedicated communication cable (D-Sub) (for NEC PC-98 Series) Model LC1-
T-brackets T-nuts Model LC1-1-L5 (Weight: 16.0g) Model LC1-1-L3 (Weight: 15.5g) M (Weight: 10.0g) M5 M3 17.5 17.5 17.5 7.5 18 12 11 Model M 20 7.5 7.5 21 LC1-1-N3 M3 x 0.5 29 30 LC1-1-N5 M5 x 0.8 Controller Connectors These are connectors 'all halfpitch type' used for CN1 (control input/output) and CN2 (general purpose input/output).
(Parameter initial configuration Set the recommended parameter value Operation start) *3 The travel distance of the actuator per 1 pulse should be 10 [m/pulse]. 25 - Recommended Parameter Values [LEJ] LEJS40 LEJS63 LEJB40 LEJB63 Series Lead symbol H A B H A B T Lead 24 16 8 30 20 10 27 42 Parameter *1,*2 Para. Initial value Recommended value No.
Heat generation amount Q : Unknown : 1.0C (1.0 K) : 20C (293.15 K) : 21C (294.15 K) : 7 L/min :Water : Density : 1 x 103 kg/m3 Circulating fluid temperature difference T (= T2 T1) Circulating fluid outlet temperature T1 Circulating fluid inlet temperature T2 Circulating fluid flow rate L Circulating fluid : Specific heat C: 4.2 x 103 J/(kgK) T1: Outlet temperature Q = T x L x x C 60 x 1000