Cylinder with Lock Series CNS Mounting style B L F G C D T Basic style Foot style Rod side flange style Head side flange style Single clevis style Double clevis style Center trunnion style Tubing material Nil F Aluminum tube Steel tube Auto switch Nil Without auto switch Auto switches are not available with steel tube. Select applicable auto switch part numbers from the table below.
QA Tubing O.D. 6 J QB Q F Built-in One-touch Fittings Stroke 13 20 Stroke 8 Applicable tubing O.D.
h11 (Shaft) f H9 (Hole) a (Max.) c (Min.) e b d l1 Part no.
Basic style: CM2YB Width across flats B2 2-P (Port size) (Rc, NPT, G) 2-NN H1 H2 G G RE A B Width across flats B1 I REC 2-Eh8 D CX MM AL A F F NA 1.5 1.5 CY N N K H S + Stroke ZZ + Stroke MQQ M RHC Boss-cut MK(2) RS Q G RS H A RZQ ZZ + Stroke MI W S CEP1 CE1 (mm) CE2 AL B1 B2 D E F G H H1 H2 I K MM N NA NN P S ZZ A Bore size (mm) 20 25 32 40 0 0.033 0 0.033 0 0.033 0 0.039 18 15.5 13 26 8
Basic style: CM2YB Width across flats B2 2-P (Port size) (Rc, NPT, G) 2-NN H1 H2 G G RE A B Width across flats B1 I REC 2-Eh8 D CX MM AL A F F NA 1.5 1.5 CY N N K H S + Stroke ZZ + Stroke MQQ M 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 RHC Boss-cut MK(2) RS
MHKL 2 20 S D 1 F M9N Long stroke type Number of auto switches Number of fingers Nil S 2 pcs. 1 pc.
Calculation of applied lateral load The lateral load F equals the total load of the workpiece. Thus, F= 5 x 0.05 x 9.8 = 2.5 (N) 1. Calculation of applied lateral load F F = N m g (N) = 0.2 x 10 x 0.1 x 9.8 = 2.1 (N) CC 70 Lateral load F (N) RB 60 0.4 MPa 50 J 40 2.
Width across flats KB B C V MM BH1 BH2 BH3 TX D E B1 C B ZZ + Stroke S + Stroke H A K BN N1 N MA MB F AL H1 TT B C B1 C B TY With rod boot d e 10.2 f h 10.2 l [mm] Bore size A AL B B1 BH1 BH2 BH3 BN BP C D E F GA GB GC GD GE GF H H1 J 32 22 19.5 46 46 23 38.5 46.5 59 1/8 32.5 12 30 13 37.5 13 37.5 18.5 4 13 47 6 M6 x 1.0 40 30 27 57 52 28.5 42.5 48.5 73 1/8 38 16 35 13 59.5 14 44.5 19.5 4
Internal Grip External Grip MHK2-12C MHK2-12S 20 15 Pressure 0.6 MPa Pressure 0.6 MPa Pressure 0.6 MPa Pressure 0.6 MPa Gripping force (N) Gripping force (N) 15 10 0.5 MPa 0.5 MPa 10 0.4 MPa 0.4 MPa 5 5 0.3 MPa 0.3 MPa F F 0 0 10 20 30 40 50 10 20 30 40 50 Note) In case of single acting type, the value is for stroke center.
upon receipt of order. 8-9-8 8 Air Slide Table Long Stroke Type Series MXY Table Deflection Table deflection due to pitch moment load Displacement at A when load is applied F Table deflection due to yaw moment load Displacement at A when load is applied F Table deflection due to roll moment load Displacement at A when load is applied F A A F A F F MX MTS L L L MY L dimension mm L dimension
10 8.5 6.5 7.5 24 10 M5 x 0.8 M14 x 1.0 M5 x 0.8 19.5 4 43.5 Built-in magnet: CDJP2B6 to 16 Z + Stroke S + Stroke H A' F GB GA 2 x P A F' Mounting nut Width across flats B1 A' Rod end nut Width across flats B2 30 D-1 D E J C MM Without rod end thread NN W B (mm) Symbol A A' B B1 B2 C D E F F' GA GB H J MM NN P S W Z Bore size 6 10 16 7 9 14 14 5.5 2 3 16.5 8 6.5 5.5 6.5 17 6 M3 x 0.5 M10
Calculation of applied lateral load F The lateral load F equals the coefficient between the work piece and the conveyor. Thus, from the total amount of the work piece and coefficient of friction, F = x m g (N) 1. Calculation of applied lateral load The lateral load F equals the total load of the work piece. Thus, F = x m g (N) 2.
Calculation of applied lateral load The lateral load F equals the total load of the workpiece. Thus, F= 5 x 0.05 x 9.8 = 2.5 (N) 1. Calculation of applied lateral load F F = N m g (N) = 0.2 x 10 x 0.1 x 9.8 = 2.1 (N) CC 70 Lateral load F (N) RB 60 0.4 MPa 50 J 40 2.
Operating pressure: 0.4 MPa Model Selection Illustration When gripping a workpiece as in the figure to the left and with the following definitions, F: Gripping force (N) : Coefficient of friction between attachments and workpiece m: Workpiece mass (kg) g: Gravitational acceleration (= 9.8 m/s2) mg: Workpiece weight (N) F F the conditions under which the workpiece will not drop are mg F F
Flange (F, G) [mm] Bore size [mm] Part no.
Head Flange: CG3GN Bore size Stroke With rubber bumper Width across flats KA GA GB 4 x FD 8 x J 2 x P F R0.5 H1 0 E 0.05 MM D FX 0.15 0 E 0.05 I B C Corner of the cover (20 to 63) H A AL Width across flats B1 Width across flats NA F FT C FX 0.15 S + Stroke ZZ + Stroke B End boss is machined on the flange for E.
Operating pressure: 0.4 MPa Model Selection Illustration When gripping a workpiece as in the figure to the left and with the following definitions, F: Gripping force (N) : Coefficient of friction between attachments and workpiece m: Workpiece mass (kg) g: Gravitational acceleration (= 9.8 m/s2) mg: Workpiece weight (N) F F the conditions under which the workpiece will not drop are mg F F
Operating pressure: 0.4 MPa Model Selection Illustration When gripping a workpiece as in the figure to the left and with the following definitions, F: Gripping force (N) : Coefficient of friction between attachments and workpiece m: Workpiece mass (kg) g: Gravitational acceleration (= 9.8 m/s2) mg: Workpiece weight (N) F F the conditions under which the workpiece will not drop are mg F F
Flange (F, G) [mm] Bore size [mm] Part no.
External Grip Internal Grip MHK2-12D MHK2-12D 25 20 Pressure 0.6 MPa Pressure 0.6 MPa Gripping force (N) Gripping force (N) 20 15 0.5 MPa 0.5 MPa 15 0.4 MPa 10 0.4 MPa 10 0.3 MPa F F 0.3 MPa 5 5 0.2 MPa 0.2 MPa 0 0 10 20 30 40 50 10 20 30 40 50 Gripping point L (mm) Gripping point L (mm) External grip Series MHK2 Internal grip Series MHK2 MHK2-16D MHK2-16D 50 50 Pressure 0.6 MPa Pressure