Process Gas Diaphragm Valve OUTLET INLET Mounting hole Top view (Mounting hole on bottom) Porting Symbols OUTLET (Downstream) INLET (Upstream) 2PW 2PWA 2PWC q q q w 2 PORTS w w 3PWD 3PWE 3PWG 3 PORTS q q q e e e w w w 4PWM q e r 4 PORTS w 1114 A
This lowers the pressure in the diaphragm chamber q and the force generated by the pressure regulator spring e pushes down the diaphragm.
The 5 port solenoid valves series SQ was designed for applications which demand high speed, high frequency, long life and a precise response time. The SQ uses cassette style valves and manifolds, making it simple to increase or decrease the number of stations on a DIN rail. Valves are available with 12VDC or 24VDC rated voltage. Actuation options include 5 port single solenoid, 5 port
The 5 port solenoid valves series SQ was designed for applications which demand high speed, high frequency, long life and a precise response time. The SQ uses cassette style valves and manifolds, making it simple to increase or decrease the number of stations on a DIN rail. Valves are available with 12VDC or 24VDC rated voltage. Actuation options include 5 port single solenoid, 5 port
The 5 port solenoid valves series SQ was designed for applications which demand high speed, high frequency, long life and a precise response time. The SQ uses cassette style valves and manifolds, making it simple to increase or decrease the number of stations on a DIN rail. Valves are available with 12VDC or 24VDC rated voltage. Actuation options include 5 port single solenoid, 5 port
Unit Size: 7 (75mm), Cup Flange Shape: A (42mm x 42mm), Manufacturer: 01 [UR: 3(e), 5(e), 10(e), 16(e)], Cup Series: ZP (Basic), Cup Diameter: 20 (ø20), Cup Form: U (Flat), Cup Material: S (Silicone Rubber , White), Attachment: with (Guide) Attachment
A B C 1 V 1.5 V 5 V 4 mA 6 mA 20 mA (PF3W511) A B C 1 V 1.4 V 5 V 4 mA 5.6 mA 20 mA (PF3W521-12/14) A B C 1 V 1.8 V 5 V 4 mA 7.2 mA 20 mA (PF3W521-U30) A B C 1 V 1.48 V 5 V 4 mA 5.92 mA 20 mA [L/min] PF3W504 0.5 4 PF3W520 2 16 PF3W540 5 40 PF3W511 10 100 PF3W521-12/14 50 250 PF3W521-U30 30 250 () A B C D 0.6 V 1 V 5 V 5.4 V -40No.PF-OMN0009CN-F PF3W504/520/540/511 2X A AA B DD E
e 40 40 32 32 1000 1000 25 25 20 20 5 500 5 500 0 0 5 10 15 20 25 30 35 40 5 10 15 20 25 30 35 40 Circulating fluid temperature Circulating fluid temperature 60Hz 50Hz Fig. 9-5 Heating capacity(HRS060-A-20-(BJM)) 9.5.2 HRS060-W-20-(BJM) 2000 2000 Ambient Ambient temperatur temperatur Heating capacityW Heating capacityW 1500 e e 1500 40 32 25 20 5 40 32 25 20 5 1000 1000 500 500 0 0 5 10 15
Power supply connector Cable Qty. x size 3cores14AWG 3cores2.0mm2 *including ground N E(Earth) L Fig 3-3 Cable connection 5. Insert the power supply connector to the power supply connector socket. 6.
P V < 2 3 . 0 o C # 1 S V 3 0 . 0 o C M O D E R e m : 0 5.10.4 Circulating fluid set temperature The circulating fluid set temperature can be set by specifying the circulating fluid target temperature during Serial Remote mode.
E E KF K Fd Fn C D H B A G A mm A B C D E Fn Fd G H XLA-16-2 40 108 38 20 30 17 44 XLA-25-2 50 121 48 27 12 40 26 44 XLA-40-2 65 171 66 39 11 55 41 67 XLA-50-2 70 185 79 46 11 75 52 72 XLA-63-2 88 212 100 55 11 87 95 70 76 XLA-80-2 90 257 117 65 11 114 110 83 104 12 XL-OMY0001 6. 200 []1 1.5 1 200 FKM 110Pa <> 13 XL-OMY0001 7 7-1. 2 2P5P6 14 XL-OMY0001 7-2 1 2 1 3 1 1 2 4 1 0.4MPa
L250) FGD-CA005 FGDC,E(L500) 7/11 FGX-OM-L007-C 2. 2.
300ms) c) Deceleration time constant (300ms) b) Acceleration time constant (200ms) a) Servo motor speed (1000r/min) a) Servo motor speed (1000r/min) Forward rotation 0r/min Servo motor speed d) Absolute move command (1000 10STM m) f) Absolute move command (2000 10STM m) e) Dwell command time (100ms) 91 - 8.
Usable stroke by buckling strength Usablestroke by Mounting style buckling strength (cm) Pressure Symbol and sketch (MPa) Symbol of bracket Rod side Frang e F Head side flange 103 92 113 Foot: 79 70 86 L G 66 58 72 45 38 47 33 27 34 26 22 27 96 83 106 Center Clevis trunnion 71 61 76 CD T 59 50 62 135 119 147 101 89 111 84 74 91 Rod side Frang e F Head side flange 301
Please refer to "Fig.1 Allowable lateral load applied to rod end ". ( Page 10) Table 2 Allowable kinetic energy CG5 N A Formula E= ( m/ 2 )v2 Bore size( mm ) E max ( J ) E max ( J ) 20 0.28 0.42 E Kinetic energy ( J ) m : Load mass ( Kg ) v Max. piston speed ( m/s ) 25 0.41 0.65 32 0.66 0.91 40 1.2 1.8 50 2.0 3.4 EE max ( J ) Should be satisfied. 63 3.4 4.9 80 5.9 11.8 100 9.9 16.7 Warning
P101. 2 CG5 N A (mm) E max (J) E max (J) 2 E=(m/2)v 20 0.28 0.42 25 0.41 0.65 E J m: (Kg) v m/s 32 0.66 0.91 40 1.2 1.8 50 2.0 3.4 EE max (J) 63 3.4 4.9 80 5.9 11.8 100 9.9 16.7 (2) 2-7. 14 28. 3 13 2 3CDG5 (M4 1~1.2Nm 3 3.
0.022 0.055 0.15 0.26 0.46 0.77 3-3-2 g (mm) mm 25 50 75 100 125 150 175 200 250 300 400 500 12 28 33 38 43 48 53 20 70 84 98 112 126 140 154 168 32 260 297 334 371 408 445 482 556 630 40 462 499 536 573 610 684 758 906 1054 50 1015 1243 1699 63 1105 1333 1789 3-3-3 2 (m1+m2)V E(J= m1 kg m2 kg V m/s 4. 4-1 CE1 4-2 A A B B C COM(OV) D COM(OV) E 12 24V F 0V G CEU5 CEU5
Since Rotary Actuator reaches the rotation end during acceleration, terminal acceleration "" can be found by = 2 / t :Rotation angle (rad) t:Rotation time (s) Since Kinetic energy E is E = 1 / 2I2 Rotation time "t" of Rotary Actuator is I 2 2 t E EAllowable kinetic energy (J) IMoment of inertia (kgm2) Rotating angle (rad) 180o = 3.14 rad In uniformly angular accelerated motion, angular
9 wyu e r i MH-A1006 MHKL2-J25 MHKL2-J25F MHKL2-J25S Order 2 pieces per one finger unit.
Shock absorber model Applicable bore (mm) CLS ML1-A25H ML1-A32H ML1-A40H ML1C25 ML1C32 ML1C40 101 90 25 20 11 72 67.3 12 31 39.5 Max. 16.5 4.5 3 RB1412 120 107 30 25 16 93 73.2 15 38 49 Max. 20 5.5 6 CLQ RB2015 147 129 30 31 16 105.5 73.2 15 40.5 54.5 Max. 25 5.5 6 MLGP Side Support RLQ Side support A MLU ML1C D-X 20Data Side support B A B C D E F G H J Part no.