MRHQ 0.8 Port A M5 x 0.8 Port B 4-M5 x 0.8 depth 8 8 22 8 12 25 11 6 6 29 Side A Side B 41 12-11-14 15 Rotary Gripper Series MRHQ MRHQ20 A MHZ B 48 59 MHF 78 MHL MHR 38.5 4-M6 x 1 depth 10 51 MHK Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com 0 -0.074 26.3 opened +2.2
8370: JIS B 8361: JIS B 9960-1: 1 ) JIS B 8433: *2) 1. 2. 3. 1. 2. 3. 4
LVC DIN terminal: D Conduit terminal: T Cable 6 to 12 LVA F S Q 27.5 34 F (Q) LVH LVD LVQ LQ R C U 25 LVN C (44) R E R TI/ TIL G1/2 E PA G1/2 A H D (S) B B A H D 2-P Port size 2-P Port size PAX 2-M Thread depth N 2-M Thread depth N PB L L K K N.C.
Model AS1ll1FSGl-M5 AS2ll1FSGl-01 AS2ll1FSGl-02 AS3ll1FSGl AS4ll1FSGl Metric size 2 3.2 4 6 3.2 4 6 8 10 3.2 4 6 8 10 6 8 10 12 10 12 16 Tubing O.D.
-6 = 9.0 x 10-6 (kgm2) Moment of inertia around Z axis IA = IZ1 + m1r12 X 10-6 z r2 z2 B part r2 = 47(mm) Calculation of weight m2 = d x e x f x Specific gravity m2 = 5 x 10 x 12 x 2.7 x 10-6 = 0.002 (kg) Moment of inertia around Z2 axis IZ2 = {m2 (d2 + e2)/12} x 10-6 IZ2 = {0.002 x (52 + 102)/12} x 10-6 = 0.02 x 10-6 (kgm2) IB = 0.02 x 10-6 + 0.002 x 472 x 10-6 = 4.4 x 10-6 (kgm2) I =
6 @5 #5 q #9 #4 !3 #2 !2 @1 !0 @2 @6 #6 #3 @8 #1 @4 o #8 !
0.31 0.26 0.27/0.33 0.29/0.41 0.35 0.42 0.36/0.34 0.29/0.30 0.29 0.23 0.18/0.23 0.19/0.18 b 0.34 0.27 0.31/0.30 0.31/0.25 0.41 0.43 0.36/0.41 0.41/0.42 0.36 0.25 0.27/0.27 0.26/0.28 b 0.47 0.40 0.38/0.40 0.57/0.21 0.34 0.36 0.30/0.26 0.17/0.14 0.31 0.22 0.25/0.24 0.24/0.23 b 0.38 0.28 0.37/0.37 0.25/0.23 0.42 0.43 0.35/0.32 0.22/0.21 0.36 0.29 0.25/0.24 0.22/0.24 VP342 (Body ported) 1/8 1
Y Y ,, IDF100F150F-W 6 7 IDX-OM-Z004 6 6.6 () (1) ADH-E400 V 1 -(2) 1 1 ) 1 2 ) Y92S-36/CR2477/ () 1 B 20,000 (6 ) 1 B 20,000 (6 ) 1 B 20,000 (6 ) 1 B 20,000 (6 ) 1 A 20,000 (6 ) 1 A 20,000 (6 ) 1 A 20,000 (6 ) 1 A 20,000 (6 ) 12 /JEMA 300 A B IDF100F150F-W 6 8 IDX-OM-Z004 7 7 7.1 / 7-1 IDF100150F-W 7 1 4-14-1, Sotokanda, Chiyoda-ku, Tokyo 101-0021 JAPAN Tel
OptionOptional Accessories . 6-1 6.1 Option J [Automatic fluid filling] . 6-1 6.1.1 Option J [Automatic fluid filling] . 6-1 6.2 Option M [DI water (Pure water) piping] . 6-2 6.2.1 Option M [DI water (Pure water) piping] . 6-2 HRS Series HRX-OM-W038 Contents 6.3 Option T [High-pressure pump] . 6-2 6.3.1 Option T [High-pressure pump] . 6-2 6.4 Optional Accessories [Electric resistivity /conductivity
Rotational axis B d D I m kgm I = m kgm 8 8 Gear: I a + b I = m kgm IB = I + I + I kgm 12 Substitute the moment of inertia IB for rotation around shaft B with the moment of inertia IA for rotation around shaft A. Gear: I IA = (A/B)IB [A/B: Gear tooth ratio] Find the actual moment of inertia.
port: Rc 1/8 Nil P port: Rc 1/8 Thread type R port: Rc 1/8 20 Type S42 Solenoid on same side of A and B port 20 stations Type VK334 Nil F N T Rc S Port size Type VK3140 G P port: Rc 1/8 1 8 01 Rc C6 6 cassette NPT R port: Rc 1/8 NPTF B port: Rc 1/8 A port: Rc 1/8 Common SUP/Individual EXH Type 21: Body ported (A, B port top ported) How to Order Applicable solenoid valve VK3120M5 VK312001
8370: JIS B 8361: JIS B 9960-1: 1 ) JIS B 8433: *2) 1. 2. 3. 1. 2. 3. 4. 4 - LEC-G Series/ 1 / 1 1.5 5 - 2 21 GWProfibus 1 5 LEC 22 DIN D DIN PR1 Profibus DP V1 G 6 - 23 PLC LEC-T1-3G Profibus (LEC-W2) LEC-GPR1 LEC RS485 Modbus ...
Screw How to Calculate the Flow Rate For obtaining the flow rate, refer to page 4-1-6. DIN Rail Removing/Mounting Removing 1. Loosen the clamp screw on the (a) side of both ends of the manifold. 2. Lift the (a) side of the manifold off the DIN rail and slide it in the direction of the (b) side. (a) Mounting 1. Catch the hook of the DIN rail bracket on the (b) side of the DIN rail. 2.
0(0) 0 o 12. 2 4(7.a B 1(0) 8 10{6. 83 88 104 0(0) 0(3) 2.5{6.5) 4.5 B 1.5(O) 1 . 5 s.st2) 8.s{4.5) 10.5 38 ,t3.5 50.5 B 3(O) 3 10{6) 12i3. = H s 40 43.5 49 55.5 42 50 B 3(0) 3 7 10(6) 12 38 50.5 59 B 3(0) 7.4 10.5(6) 12.5 40 43.5 4S 55.5 35 42 50 Acrtssofies $eries CLA Di mensions Of Accessories lType Single Knuckle Joint Y Type Double Knuckle Joint Malerial: Free cutting sulfer steel l
digit and lower 6-digit (total of 12 digits) display.
0(0) 0 o 12. 2 4(7.a B 1(0) 8 10{6. 83 88 104 0(0) 0(3) 2.5{6.5) 4.5 B 1.5(O) 1 . 5 s.st2) 8.s{4.5) 10.5 38 ,t3.5 50.5 B 3(O) 3 10{6) 12i3. = H s 40 43.5 49 55.5 42 50 B 3(0) 3 7 10(6) 12 38 50.5 59 B 3(0) 7.4 10.5(6) 12.5 40 43.5 4S 55.5 35 42 50 Acrtssofies $eries CLA Di mensions Of Accessories lType Single Knuckle Joint Y Type Double Knuckle Joint Malerial: Free cutting sulfer steel l\
(M4),90 , -9 M4 1.5Nm -10 14 - 6-3. 5080 O 6-3-1. 4 50 : 12.5Nm 63 : 24.5Nm 80 : 42.0Nm -11 6-3-2. 1) -12 -12 2) 15 - 6-3-3. GR-S-010(10g),GR-S-020(20g) 1) 2) 3)O 4) -13 -13 6-3-4. 1)() -14 2)() -14 16 - 6-4. 6-4-1. B , 1 6-4-2. 7. 7-1.
Start-up . 6 3.1 Preparation . 6 (1) Software installation . 6 (2) Installation and wiring . 6 3.2. Start-up . 6 (1) Supply of power . 6 (2) Start-up of the Controller setting software . 6 (3) Alarm check . 8 4.
Incorrect internal data processing of the product (Er0, 4, 6, 8, 40) Check if there is a noise source nearby.
VCA20-12-1A 41 52 30 40 4.5 6 VCA30-12-1A 48 56 36 44 5.5 7 VCA40-12-1A 50 62 38 50 5.5 7 3 Direct Operated 2 Port for Air Series VCA Dimensions Grommet: G Conduit: C Approx. 300 Approx. 280 Q F D Q F D G1/2 C R C R L IN E E Manual override A B B A 2-P Port size 2-P Port size Manual override 2 L K 2-M Thread depth 6 2-M Thread depth 6 K DIN connector: D Conduit terminal: T F F (Q) Q S 34