Magnetically Coupled Rodless Cylinder E Es Note 3) Bore size determination NG Determination of allowable stroke (W + WB) V 2 E = x ( ) 2 1000 E Es Note 2) OK Determination of pressure (P) when making intermediate stop Review of order made products based on operating conditions P Ps Note 1) This cylinder cannot perform an intermediate stop using an air pressure circuit in vertical operation.
Standard Strokes Bore size (mm) Standard strokes (mm) 40 50 63 80 100 125 160 25 to 800 25 to 800 25 to 800 25 to 1000 25 to 1000 Specifications with included auto switch are the same for Double Acting/Single Rod.
200, 250, 300 63 350, 400, 450, 500, 600, 700, 800, 900, 1000, 1100 MGGL Ball bushing 80 350, 400, 450, 500, 600, 700, 800, 900, 1000, 1100, 1200 100 350, 400, 450, 500, 600, 700, 800, 900, 1000, 1100, 1200, 1300 Intermediate strokes and short strokes other than the above are produced upon receipt of order.
F G D T F G D F F G E S F G E L F G E T F G G S F G G L Fluid name Applicable element type, material Nominal filtration accuracy (m) Fiber element Polypropylene 10 Industrial water Fiber element Polypropylene 20 Water for cleaning Fiber element Polypropylene 20 Water Fiber element Cotton 10 Fragrances Micromesh element Stainless steel 316 10 Hot water Micromesh element Stainless steel 316
No anchor bolt is included. 139 A HRSH090 Series Inverter Type * If the product is used at altitude of 1000 m or higher, refer to Operating Environment/ Storage Environment (page 151) Item 14 * For altitude of 1000 m or higher.
Weight Model LEFB16 LEFB25 Stroke(mm) 300 500 600 700 800 900 1000 300 500 600 700 800 900 1000 1200 1500 1800 2000 Weight(kg) 1.19 1.45 1.58 1.71 1.84 1.97 2.10 2.39 2.85 3.08 3.31 3.54 3.77 4.00 4.46 5.15 5.84 6.30 Additional weight for lock(kg) 0.12 0.26 Model LEFB32 Stroke(mm) 300 500 600 700 800 900 1000 1200 1500 1800 2000 Weight(kg) 4.12 4.80 5.14 5.48 5.82 6.16 6.50 7.18 8.20 9.22
(For details, refer to page 4-4-25.) 4-4-20 21 3 Port Pilot Operated Solenoid Valve Rubber Seal Series SYJ500 Construction q e r t w y q e r t w y N.C. N.O.
With External Pilot Specifications (Pitch) 24 P = 24 65.8 20 25 11 E 3/5 E 3/5 E 3 A E 3 A 4 A 4 A 4 A 4 A 4 4 A 4 A 4 A 4 A 4 13.7 14.5 35.8 35 58.3 74.8 P 1 P 1 B 2 B 2 B 2 B 2 B 2 P 1 P 1 B 2 B 2 B 2 B 2 B 2 One-touch fitting [1(P), 3/5(E) port] Applicable tubing O.D.: 12 3/8" One-touch fitting [4(A), 2(B) port] Applicable tubing O.D.: 8, 5/16" 10, 3/8" 12 X PE X PE Rc 3/8 [1(P), 3(E)
A B C E D G E ZPT40 U C ZPT50 U C ZPT10 U C ZPT13 U C ZPT16 U C 19.5 6.2 8 6 3.3 32 6.5 40 43 18.5 10 12 1.7 12 3 27 21 21 33 7.5 3.8 50 53 6.2 12 5 8 8 6 13 15 1.8 12.5 3.5 27.5 21.5 21.5 16 18 1.2 Deep Deep 1 8 B C D D E Y F: M6 x 1 F: M8 x 1.25 D F: Rc Model A 1 8 D G F: Rc Y B C E D G E D G F: M5 x 0.8 F: M6 x 1 E Model A ZPT40D 40 43 29 6 8 6.2 17 42.5 ZPT10D ZPT16D 10 16 12 18 15 16
E Es Note 3) Bore size determination NG Determination of allowable stroke (W + WB) V 2 E = x ( ) 2 1000 E Es Note 2) OK Determination of pressure (P) when making intermediate stop Review of order made products based on operating conditions P Ps Note 1) This cylinder cannot perform an intermediate stop using an air pressure circuit in vertical operation.
Local Area: (800) 258-9200-www.stevenengineering.com 1 420 2 E = x 1 () = 0.088 2 1000 Find the kinetic energy E (J) of the load. ) Correction factor (Reference values) V = 1.4 x 300 = 420 Find the allowable kinetic energy Ea (J).
0 200 400 600 800 1000 1200 1400 1600 Stroke [mm] Stroke [mm] [Graph 7] Allowable load mass by stroke 40 100 y, z + A = 0 y, z + A = 50 Load mass [kg] y, z + A = 100 y, z + A = 200 10 y, z + A = 300 1 0 200 400 600 800 1000 1200 1400 1600 If load center of gravity exceeds the value of y, z + A on the graph, please consult SMC.
L1 L2+A5 L3 2 1 V 2 E = W () 2 1000 Collision speed V = 1.4 Va 1 420 2 E = 1 () = 0.088 2 1000 Find the kinetic energy E (J) of the load. ) Correction factor (Reference values) V = 1.4 x 300 = 420 Ea = K E max Find the allowable kinetic energy Ea (J). Confirm that the kinetic energy of the load does not exceed the allowable kinetic energy.
R O D T H R E A D S T D. R O D B O R E S I Z E 7/16-20 7/16-20 7/16-20 3/4-16 3/4-16 3/4-16 1-14 1-14 1 1/4-12 1 1/2-12 1 7/8-12 5/8 5/8 5/8 1 1 1 1-3/8 1-3/8 1-3/4 2 2-1/2 S TA N D A R D S T R O K E 150 1.5 200 2 250 2.5 325 3.25 400 4 500 5 600 6 800 8 1000 10 1200 12 1400 14 E 1 G 1 3/8 H 1 3/4 J 2 K 2 1/2 L 3 M 3 1/2 Z Please consult P/A Customer Service for larger sizes.
R O D T H R E A D S T D. R O D B O R E S I Z E 7/16-20 7/16-20 7/16-20 3/4-16 3/4-16 3/4-16 1-14 1-14 1 1/4-12 1 1/2-12 1 7/8-12 5/8 5/8 5/8 1 1 1 1-3/8 1-3/8 1-3/4 2 2-1/2 S TA N D A R D S T R O K E 150 1.5 200 2 250 2.5 325 3.25 400 4 500 5 600 6 800 8 1000 10 1200 12 1400 14 E 1 G 1 3/8 H 1 3/4 J 2 K 2 1/2 L 3 M 3 1/2 Z Please consult SMC Customer Service for larger sizes.
L1 L2+A5 L3 2 1 W V 2 E= ( ) 2 9.8 1000 Collision speed V=1.4 Va *) Corrected coeficient 1 420 E= 1( ) =0.088 2 1000 V=1.4 X 300=420 Calculate kinetic energy E (J) of work. Calculate allwable kinetic energy Ea (J). Check that kinetic energy of work does not exceed allowable kinetic energy.
BC PH MM H1 PD E 0 0.05 E 0 0.05 I BZ TH Width across flats B1 Width across flats KA Width across flats NA 8-J TT TY TW C0. 1 TX TE +0.10 0 4-TF TV TZ BC Z ZZ + Stroke f 8 l e h + l ZZ + l + Stroke Z + l With rod boot (mm) Bore size (mm) Stroke range without rod boot Standard Long stroke 20 25 32 40 Stroke range with rod boot Standard Long stroke A AL B1 BC BN BP BZ C D E F GA GB GC GK GL