Rotary Table Rack & Pinion Style Series MSQ Size: 1, 2, 3, 7, 10, 20, 30, 50, 70, 100, 200 1

Next, B is entered to find A the inertial moment for the rotation of shaft (A) as 5 b a A = ( ) 2 B Number of teeth = b Kinetic Energy/Rotation Time Even in cases where the torque required for rotation of the load is small, damage to internal parts may result from the inertial force of the load.

Angle Seat Valve /

is b = 0.3.

Rotary Table/

bolt B Adjustment bolt B Adjustment bolt B adjustment amount adjustment amount adjustment amount 90 Rotation 90 Rotation 90 Rotation 9 Rotary Table Series MSQ Construction o i t !

MXW Series Long Stroke Slide Table

L3 Item Load factors n Note (1) Max. movable load W B L2 Examine W.

Series CM2-Z 10-/11- ø20, ø25, ø32, ø40 21-/22- Air Cylinder

Fittings & Tubing Air Cylinders Rotary Actuators Clean series 10 11 Relief type Vacuum suction type 10 C D B M 2 B 20 100 H N M9BW C 21 C D B M 2 B 20 100 H N M9BW C Nil Built-in magnet Number of auto switches Cylinder stroke (mm) No Nil S n 2 pcs. 1 pc. "n" pcs.

MY1

C D Side support B MY-SB 2-J 2-H C D A B J M4 x 0.7 M5 x 0.8 M6 x 1 M8 x 1.25 C 15 25 35 45 E 4.9 6.4 8 11.7 F 3 4 5 6 H 3.4 4.5 5.5 6.6 G 6.5 8 9.5 11 A 61 67 81 100 120 142 172 D 26 38 50 64 B 71.6 79.6 95 118 142 164 202 Applicable cylinder MY1W16 MY1W20 MY1W25 MY1W32 MY1W40 MY1W50 MY1W63 Model MY-S16A B MY-S20A B MY-S25A B MY-S32A B M10 x 1.5 55 14.8 8.5 9 14 80 MY-S40A B M12 x 1.75 70

Booster Regulator/Air Tank

END 1014 Booster Regulator VBA Series Working Principle The IN air passes through the check valve to booster chambers A and B. Meanwhile, air is supplied to drive chamber B via the governor and the switching valve. Then, the air pressure from drive chamber B and booster chamber A are applied to the piston, boosting the air in booster chamber B.

Mechanically Jointed Rodless Cylinder With Protective Cover Series MY1  W ø16, ø20, ø25, ø32, ø40, ø50, ø63 1

C D Side support B MY-SB 2-J 2-H C D A B (mm) A B C 15 25 35 45 E F G D H J M4 x 0.7 M5 x 0.8 M6 x 1 M8 x 1.25 Applicable bore size MY1W16 MY1W20 MY1W25 MY1W32 MY1W40 MY1W50 MY1W63 Model MY-S16 MY-S20 MY-S25 MY-S32 61 67 81 100 120 142 172 26 38 50 64 4.9 6.4 8 11.7 3 4 5 6 6.5 8 9.5 11 3.4 4.5 5.5 6.6 A B A B A B A B 71.6 79.6 95 118 142 164 202 80 14.8 8.5 14 9 A B 55 MY-S40 M10 x 1.5 A

C95

GD GC EE SW EE SW1 KK WA WA WB B D B ??

MY1

C D Side support B MY-SB 2 x J 2 x H C D A B A B C D E F G H J Applicable cylinder MY1W16 MY1W20 MY1W25 MY1W32 MY1W40 MY1W50 MY1W63 Model MY-S16A 61 71.6 15 26 4.9 3 6.5 3.4 M4 x 0.7 B MY-S20A 67 79.6 25 38 6.4 4 8 4.5 M5 x 0.8 B MY-S25A 81 95 35 50 8 5 9.5 5.5 M6 x 1 B MY-S32A 100 118 45 64 11.7 6 11 6.6 M8 x 1.25 B 120 142 MY-S40A M10 x 1.5 55 80 14.8 8.5 14 9 B 142 164 MY-S63A 172 202

51

D-H7W D-H7NF D-H7BA D-C7/C8 D-H7 D-H7C D-H7W D-H7BA D-H7NF D-G5/K5 D-G5W D-K59W D-B5/B6 D-B59W D-G5NT D-G59F D-H7C D-G5BA D-M9V D-M9WV D-M9AV D-A9V D-C7/C8 D-C73C D-C80C D-M9(V) D-M9W(V) D-M9A(V) D-C73C D-C80C D-B5 D-B6 D-B59W D-A9(V) A B A B A B A B A B A A B B 28.5 29 30.5 31 42.5 42.5 Hs 25.5 28 31.5 36 41.5 48.5 Hs 24.5 27 30.5 35 40.5 47.5 Hs 27 29.5 33 37.5 43 50 Hs 27.5 30

Multi-Axis Step Motor Controller

A B-1 A A-1 B B-2 B A-2 COM-A/COM B-3 COM-B/ A-3 Cable type Nil Robotic cable (Flexible cable) S Standard cable Cable color Connector D terminal no.

Mechanically Jointed Rodless Cylinder with Protective Cover Series MY1W

C D Side support B MY-SB 2-J 2-H C D A B J M4 x 0.7 M5 x 0.8 M6 x 1 M8 x 1.25 C 15 25 35 45 E 4.9 6.4 8 11.7 F 3 4 5 6 H 3.4 4.5 5.5 6.6 G 6.5 8 9.5 11 A 61 67 81 100 120 142 172 D 26 38 50 64 B 71.6 79.6 95 118 142 164 202 Applicable cylinder MY1W16 MY1W20 MY1W25 MY1W32 MY1W40 MY1W50 MY1W63 Model MY-S16A B MY-S20A B MY-S25A B MY-S32A B M10 x 1.5 55 14.8 8.5 9 14 80 MY-S40A B M12 x 1.75 70

CRQ2

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.

ML2B

Side support B MY-SB 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 2-J C D A B (mm) A 61 70 87 B 75 84 105 C D E F G H J Part no.

ML2B

Side support B MY-SB 2-J C D A B (mm) A 61 70 87 B 75 84 105 C D E F G H J Part no.

Compact Rotary Actuator Rack-and-Pinion Type/Sizes: 10, 15, 20, 30, 40 Series CRQ2

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.

CJ5-S

Applicable bore size (mm) A1 L NDd9 MM B C d H B C d H CEP1 0.030 0.060 0.030 0.060 Y-J010SUS 10 SNJ-016SUS 10 NTJ-010SUS 10 3.3 7 8 15.2 21 M4 x 0.7 16.2 M10 x 1.0 4 8.1 M4 x 0.7 3.2 Y-J016SUS SNKJ-016SUS NTJ-015SUS 16 16 16 5 17 8 11 16.6 21 M5 x 0.8 19.6 M12 x 1.0 4 9.2 M5 x 0.8 4 CE1 NDH10 U1 NX R1 Part no.

CJ5-S

Applicable bore size (mm) A1 L NDd9 MM B C d H B C d H CEP1 0.030 0.060 0.030 0.060 Y-J010SUS 10 SNJ-016SUS 10 NTJ-010SUS 10 3.3 7 8 15.2 21 M4 x 0.7 16.2 M10 x 1.0 4 8.1 M4 x 0.7 3.2 Y-J016SUS NTJ-015SUS SNKJ-016SUS 16 16 16 5 17 8 11 16.6 21 M5 x 0.8 19.6 M12 x 1.0 4 9.2 M5 x 0.8 4 CE1 NDH10 U1 NX R1 Part no.

End Lock Cylinder Series CBM2/ø20, ø25, ø32, ø40 Series CBA1/ø40, ø50, ø63, ø80, ø100 CL MLGC CNA CB CV/MVG Maintains the cylinder’s CXW original position even if the CXS air supply is interrupted. CXT MX

0(0) 0(0) 0.5(0) 5.5 A 6(4) 6(4) 7(5) 12 B A B 1.5(0) 1.5(0) B 0(0) 0(0) 1(0) 6 B 5(3) 5(3) 6(4) 11 A 7(5) 7(5) 8(6) 13 A B 6(4) 6(4) 7(5) 12 A 4(2) 4(2) 5(3) 10 B 3(1) 3(1) 4(2) 9 A 0.5(0) 0.5(0) 1.5(0) 6.5 Hs 22.5 25 28.5 32.5 Hs 25 27.5 31 35 Hs 60 62.5 66 70 Hs 69.5 72 75.5 79.5 Bore (mm) 20 25 32 40 4.5(2.5) 3.5(1.5) 2.5(0.5) 4.5(2.5) 3.5(1.5) 2.5(0.5) MGF 2.5(0.5) 7.5 5.5(3.5) 10.5