LEY-OM007 -10 (INC) c 10[mm] 0 10 20 30 40 50 [mm] -27- 4 a b c d e f g h i j k No. 1 2 mm/s mm mm/s^2 mm/s^2 % % mm/s % mm mm mm 0 ABS 100 20.00 3000 3000 80 40 30 100 10.00 20.00 20.00 No.00[mm] 20[mm]20[mm] 1 10 W [mm] c [mm] k 20 0 10 20 30 40 50 [mm] INP 2 k INPON g 30 W [mm] c [mm] k 20 0 10 20 30 40 50 [mm] INP INPOFF () k g BUSYONOFF -28- 5 a b c d e f g h i j k No. 1 2 mm/
40 120.5 46.5 104.5 65 12.5 19 58.5 35 27 14 20 14 15 2063 16.5 11 18 32 9 Up to 600 90 1/4 20 45 134.5 56.5 119.5 75 17.5 23 68 35 27 14 20 14 12 80 19 13 22 37 11.5 Up to 750 30 102 1/4 45 169 72 150 95 22 33 81 40 32 22 25 20 18 Data 100 19 16 26 37 17 Up to 750 30 116 1/4 55 189 114 89 170 25 37.5 96 40 41 22 30 20 20 Bore size (mm) T V VA W ZZ L S RR U GE GF J K MM N P Q H Z 32 M10
75 1/4 40 120.5 65 46.5 104.5 12.5 19 58.5 35 27 14 20 14 15 2063 16.5 11 32 18 9 Up to 600 90 1/4 20 45 134.5 75 56.5 119.5 17.5 23 68 35 27 14 20 14 12 80 19 13 37 22 11.5 Up to 750 102 1/4 30 45 169 95 72 150 33 22 81 40 32 22 25 20 18 Data 100 19 16 26 37 17 Up to 750 30 116 1/4 55 189 114 89 170 37.5 25 96 40 41 22 30 20 20 Bore size (mm) T V VA W ZZ L S RR U GE GF J K MM N P Q H Z
Contents 9.4 Cooling capacity . 9-9 9.4.1 HRR010-A -10. 9-9 9.4.2 HRR010-W-10. 9-9 9.4.3 HRR010-A -20. 9-10 9.4.4 HRR010-W-20. 9-10 9.5 Heating capacity . 9-11 9.5.1 HRR010-A-10. 9-11 9.5.2 HRR010-W-10. 9-11 9.5.3 HRR010-A-20. 9-12 9.5.4 HRR010-W-20. 9-12 9.6 Pump capacity. 9-13 9.6.1 HRR010-A/W-10 . 9-13 9.6.2 HRR010-A/W-10-T1 . 9-13 9.7 Required facility water flow (for water-cooled type
Q w l Y w H w Y w l l " i I I I r r l i | v l l . s o w d ; l w | v w f f Y L : f <.t __ I i i Y f Fw -t wl5uwl sor-;sS sownsot Y r.L. rr 5 r r a r s o s o w l s o w f s o v l , * ; * 1 i ' l , l -1 l a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a a MX9IEtr-@EHN+NE_I T l I r I I I I l I o , o o @ o a @ @ @ esrio" ruup @Auto switch
132 11 16 13 40 100 13 340 1/2 66 140 12 20 16 47 125 15 340 1/2 77 140 12 20 16 55 160 20 375 3/4 94 159 12 24 20 60 421 CHAW Series Dimensions Rod flange type: CHAWF 4 x FD 4 x J 2 x Rc P T T V V Cushion adjustment screw GA Air release GA M Width across flats G Width across flats G MM MM R (max.) d d W W D E E D FY B C MA a a FT MA B F NA NA F K A A K H + Stroke S + Stroke FX H ZZ + 2
per square mtr Newton Earth acceleration m I m2 mt m s'' s ' m s-2 m2 kg N a,F,1-6,e.p A,S v v a) J F G = kg ' rn's'2 9.80665 m's-2 N Impulse Ns Newton Second w E , W E , W M P Work Potential energy Kinetic energy Torque Power Joule = Newton meter Joule Joule Joule Watt J J t ' J w = kg . m2's-2 0.5-m-i = J's-l 3.
(SNJ-016B for 10, SNKJ-016B for 16) MB1 NN NB NA MM H GB GA FZ FY FX FT FC FB F CB CA BB BA Z A S Bore size (mm) 10 16 KA 9.5 12.5 M4 x 0.7 4.2 28 5 8 42 20 33 2.3 5.5 17.5 8 14 17 12 15 74 15 46 M10 x 1.0 CA2 9.5 12.5 M5 x 0.8 5.2 28 5 8 42 20 33 2.3 5.5 19 8 20 20 18.3 18.3 75 15 47 M12 x 1.0 CS1 Double Clevis Style (D) C76 CJ2KD Bore size Stroke C85 Z + Stroke S + Stroke C95 +0.030 0 Rod
P kit F kit T kit PS (Side entry) FS (Side entry) Note 1) S kit is composed of a flat cable housing assembly (AXT1002PU20) of q SI unit and w P kit (20 pin).
S CAC408 50 50A Flange T Conduit With surge voltage suppressor 100 VAC G N.O. U 110 VAC V 200 VAC W 230 VAC Z Other voltages Note) For the class H type DIN terminal, use it in combination with the connector provided.
Load Mass W CY1HT32 W Maximum Load Mass (kg) 50 40 30 CY1H25,CY1HT25 25 CY1H20 20 16 Load mass kg CY1H15 Wmax Model 10 9 CY1H10 4.0 CY1H10 5 4 3 CY1H15 9.0 2 CY1H20 16.0 1 CY1H25 W 25.0 CY1HT25 0.5 CY1HT32 40.0 70 100 300 500 1000 W Piston speed mm/s Graph (1) Moment M1,M3 M2 Allowable Moment (Static moment/Dynamic moment) 100 100 85 96 CY1HT32 CY1HT25 CY1H25 CY1H20 CY1H15 CY1HT32 CY1HT25
per square mtr Newton Earth acceleration m I m2 mt m s'' s ' m s-2 m2 kg N a,F,1-6,e.p A,S v v a) J F G = kg ' rn's'2 9.80665 m's-2 N Impulse Ns Newton Second w E , W E , W M P Work Potential energy Kinetic energy Torque Power Joule = Newton meter Joule Joule Joule Watt J J t ' J w = kg . m2's-2 0.5-m-i = J's-l 3.
15 18 14 16 21 25 19 22 27 34 13 13 15 15 14 16 26 26 17 19 32 32 20 22 28 33 32 40 50/63 80/100 1.11-10 ISO Cylinder/Standard: Double Acting Series C95K 32, 40, 50, 63, 80, 100 How to Order CJ1 C95KD B 32 100 W A53 S Standard CJP CJ2 Number of auto switches CM2 Built-in magnet 2 1 3 n S 3 n C85 Auto switch Mounting Without auto switch Bore size Basic/without bracket Axial foot Front flange
40 14 12 100 52 120 104.5 15.5 58.5 18 19 77 75 to 600 9 32 63 1/4 35 27 11 134.5 56.5 20 45 14 12 115 62 135 119.5 16.5 68 18 23 92 90 to 600 9 32 80 1/4 40 32 13 169 72 25 45 20 16 126 63 153 150 19 81 22 33 100 102 to 750 12 37 100 1/4 40 41 16 189 89 30 55 20 16 150 75 178 170 19 96 26 37.5 120 116 to 750 14 37 Bore size (mm) J T P MM N S V GF K Q H W ZZ GL GL1 GR GE VA 34 1/8 M10 x
XLS-16XLS16-20-G, C, T, D XLS-16-P XLS16-20-PG XLS-25XLS25-20-G, C, T, D XLS-25-P XLS25-20-PG Description Construction No. w y r e-1 e-2 Coil assembly Core assembly Armature assembly O-ring O-ring XLS25-30-1 XLS25-30-2 AS568-018V AS568-030V XLS16-30-1 XLS16-30-2 AS568-018V AS568-025V 465 b
LZ LC3F2 T4 = 0.2 [s] Calculation example) T1 to T4 can be calculated as follows. 200 T1 = V/a1 = 200/3000 = 0.067 [s], T3 = V/a2 = 200/3000 = 0.067 [s] 160 Overhang: L1 [mm] T2 = = = 0.033 [s] L 0.5 V (T1 + T3) V 20 0.5 200 (0.067 + 0.067) 200 120 T4 = 0.2 [s] 80 Therefore, the cycle time can be obtained as follows.
impact: P = 0.5MPa For 40 Horizontal impact: P = 0.5MPa 2000 1500 2000 1500 Impact speed (mm/s) Impact speed (mm/s) L-unit 1000 1000 Air cushion 500 400 300 500 400 300 L-unit Air cushion 200 200 Caution 1002 3 4 5 10 20 50 100 1 2 3 4 5 10 20 30 400 50 1.