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

Horizontal mounting MX MTS MY CY MG 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.

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

MXS MXQ MXF MXW MXP Locked MG rWhen air pressure is supplied to the head side, this pressure pushes the lock piston upward to disengage the lock. MGP MGQ MGG MGC Unlocked MGF tAs the lock has been disengaged, the cylinder moves forward.

End Lock Cylinder Series CBM2/ø20, ø25, ø32, ø40 Series CBA1/ø40, ø50, ø63, ø80, ø100 CL Locking of door Prevention of dropping at the rising end MLG With front lock With rear lock CNA CNG MNB CNS Maintains the cylinder’s CLS original position even if t

MXF MXW MXP Locked Unlocked MG Unlocked MGP tAs the lock has been disengaged, the cylinder moves forward.

MHC2

Number of fingers and therefore, mg F 2 x With "a" as the safety margin, F is determined as follows: mg F = x a 2 x When = 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which

MHF2

= 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which is at least 10 to 20 times the workpiece weight.

10

force at least 10 to 20 times the workpiece weight The 10 to 20 times or more of the workpiece weight recommended by SMC is calculated with a margin of a = 4, which allows for impacts that occur during normal transportation, etc. 2 x F > mg Number of fingers and therefore, When = 0.2 When = 0.1 mg F > 2 x mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 With a representing the margin, F is determined

MHZ

the workpiece will not drop are F F mg 2 x F > mg Number of fingers Gripping force at least 10 to 20 times the workpiece weight The 10 to 20 times or more of the workpiece weight recommended by SMC is calculated with a safety margin of a = 4, which allows for impacts that occur during normal transportation, etc. and therefore, When = 0.2 When = 0.1 mg F > 2 x mg F = x 4 2 x 0.2 mg F =

MHC2

Number of fingers and therefore, mg F 2 x With "a" as the safety margin, F is determined as follows: mg F = x a 2 x When = 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which

MHF2

= 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which is at least 10 to 20 times the workpiece weight.

MHZ

the workpiece will not drop are F F mg 2 x F > mg Number of fingers Gripping force at least 10 to 20 times the workpiece weight The 10 to 20 times or more of the workpiece weight recommended by SMC is calculated with a safety margin of a = 4, which allows for impacts that occur during normal transportation, etc. and therefore, When = 0.2 When = 0.1 mg F > 2 x mg F = x 4 2 x 0.2 mg F =

MHF2

= 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x work piece weight 20 x work piece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which is at least 10 to 20 times the work piece weight.

MHZ2/MHZJ2

= 0.1 mg F = x 4 2 x 0.2 and therefore, mg F > 2 x mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg With "a" representing the extra margin, F is determined by the following formula: 10 x work piece weight 20 x work piece weight Note) Even in cases where the coefficient of friction is greater than = 0.2, for reasons of safety, a gripping force should be selected which is at least 10 to 20 times

Angular Style Air Gripper Series MHC2/MHCA2/MHCM2

mg F = x a 2 x When = 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which is at least 10 to 20 times the workpiece weight.

Parallel Style Air Gripper Series MHZ

Number of fingers and therefore, When = 0.2 When = 0.1 mg F > 2 x mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 With a representing the extra margin, F is determined by the following formula: = 10 x mg = 20 x mg mg F = x a 2 x 10 x Workpiece weight 20 x Workpiece weight Note) Even in cases where the coefficient of friction is greater than = 0.2, for reasons of safety, select a gripping force

Low Profile Air Gripper Series MHF2

Number of fingers and therefore, mg F 2 x With "a" as the safety margin, F is determined as follows: mg F = x a 2 x When = 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x workpiece weight 20 x workpiece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, SMC recommends selecting a gripping force which

Angular Air Gripper Series MHC2/MHCA2/MHCM2

Number of fingers and therefore, mg F 2 x With "a" as the safety margin, F is determined as follows: mg F = x a 2 x When = 0.2 When = 0.1 mg F = x 4 2 x 0.2 mg F = x 4 2 x 0.1 = 10 x mg = 20 x mg 10 x work piece weight 20 x work piece weight (Note) Even in cases where the coefficient of friction is greater than = 0.2, for safety reasons, P/A recommends selecting a gripping force which

MGC

Rear plate 2-0 through MX A MTS U W A MY CY R V AP MG Y + Stroke Z + Stroke AB 4-AK hole 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 CX For 4-A0 D-X 20Cutout window WH (Max.)

MXH

MG 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 Application example CX Stroke (mm) Traveling parallelism 5 to 30 0.05 mm or less 40 to 60 0.1 mm or less D-X 20Auto switches offer numerous variations Reed switch, solid state switch, and 2-color indication solid

Air Slide Table Long Stroke Type Series MXY ø6, ø8, ø12 1

1 Air Slide Table Long Stroke Type Series MXY 6, 8, 12 MX MTS MY CY MG 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 CX MXP D-X 20Data A long stroke type of Series MXP air slide table with integrated linear guide is newly released. 8-9-1 2 Use of linear guide provides

7.4

) 22.8 10.5 7.4 58.5 39.7 41.8 9.2 22 28.5 22.9 20.4 10.5 8 8 3 x C2, C4, N1, N3 <1(P), 5(EA), 3(EB) port> C2: 2 One-touch fitting C4: 4 One-touch fitting N1: 1/8" One-touch fitting N3: 5/32" One-touch fitting 8.7 With plug connector/light, built-in silencer S0716S-mM(O)-m 16.7 2-Position Double/4-Position Dual 3-Port Grommet: S07 6-mG-m 2 A B C 8 2 x 3.2 5.3 2 x C2, C4, N1, N3 <4(A), 2