Compact Type Dual-Rod Cylinder Series CXSJ D-F9BAL Bore size (mm) D 18.5 16 -9 -6 -4 -3.5 B 2 9 12 14 14.5 C 0.5 10.5 16.5 24 25 34 A 18.5 28.5 34.5 42 43 52 6 10 15 20 25 32 A C Electrical entry direction: Inward Electrical entry direction: Outward Auto Switch Mounting Dimensions (mm) CXSJ6, 10 C3 Bore size 6, 10 0.4 0.4 7.2 4.8 7.2 4.8 B1 Symbol Auto switch model C2 D2 D1 A1 B1 C1 C2, C3 D1 D2 D-A9 D-F9, D-F9 W,D-M9 C1 A1 D-A9V
24 24 9 18 21 21 43 43 28 28 17 26 44 44 54 23 23 39 3.6 LQ1T41-R12 6 12 12 29 26 54 39 3.6 LQ1T41-R22 10 6 12 6 24 20 24 9 18 21 21 43 38.5 43 28 23 28 3.6 LQ1T41-R23 6 6 12 7 20 29 14 28 17 26 44 44 54 23 39 3.6 LQ1T41-R26 12 3 12 6 24 15 24 9 18 21 14 21 43 33 43 28 16.5 28 1.8 LQ1T41-R32 6 12 6 15 24 15 14 21 14 33 43 33 16.5 28 16.5 3.6 LQ1T41-R34 3 12 3 1.8 LQ1T51-R2 19 10 19 7 29 20
Actuating solenoid valve electric signal Valve opening O After a few seconds at 10-6Torr 90% 100% 90% Valve closing Operation time Responce time Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2+...1/Cn) when in series, and C=C1+C2+...Cn, when in parallel. 39 Series XL Technical Data 5 He leakage
Actuating solenoid valve electric signal Valve opening O After a few seconds at 10-6Torr 90% 100% 90% Valve closing Operation time Responce time Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2+...1/Cn) when in series, and C=C1+C2+...Cn, when in parallel. 39 Series XL Technical Data 5 He leakage
Applicable shaft types: J, X, Z d1 = d1 = d1 = d1 = L2 = Y = C2 J axis X axis D2 = C2 = C K axis T axis (mm) (mm) (mm) d1 Size 30 50 63 80 100 d1 Size 30 50 63 80 100 Y 3 to 25 1 to 36 1 to 41 1 to 50 1 to 60 L2 max Y 2 Y Y Y Y D2 5 to 7.9 5 to 14.9 5 to 16.9 8 to 19.9 8 to 24.9 Size 30 50 63 80 100 2.5 4 to 7.5 4 to 8 6.8 to 11 6.8 to 13 2.5 4 to 7.5 4 to 8 6.8 to 11 6.8 to 13 11-7
Applicable shaft types: J, X, Z d1 = d1 = d1 = d1 = Y = C2 J axis X axis K axis T axis D2 = C2 = C L2 = [mm] [mm] [mm] Size Y L2max D2 30 3 to 25 Y-2 5 to 7.9 50 1 to 36 Y 5 to 14.9 63 1 to 41 Y 5 to 16.9 80 1 to 50 Y 8 to 19.9 100 1 to 60 Y 8 to 24.9 Size d1 30 2.5 50 4 to 7.5 63 4 to 8 80 6.8 to 11 100 6.8 to 13 Size d1 30 2.5 50 4 to 7.5 63 4 to 8 80 6.8 to 11 100 6.8 to 13 218
Applicable shaft types: J, X, Z d1 = d1 = d1 = d1 = L2 = Y = C2 J axis X axis D2 = C2 = C K axis T axis (mm) (mm) (mm) d1 Size 30 50 63 80 100 d1 Size 30 50 63 80 100 L2 max Y 2 Y Y Y Y Y 3 to 25 1 to 36 1 to 41 1 to 50 1 to 60 D2 5 to 7.9 5 to 14.9 5 to 16.9 8 to 19.9 8 to 24.9 Size 30 50 63 80 100 2.5 4 to 7.5 4 to 8 6.8 to 11 6.8 to 13 2.5 4 to 7.5 4 to 8 6.8 to 11 6.8 to 13 11-7
(If not specifying dimension C2, indicate instead.)
K V 1 10 XLA S P1P2 XL XL Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2++1/Cn) when in series, and C=C1+C2++Cn, when in parallel.
Controller side PLC side For 4 Axes JXC73/83 L JXC C2 (Terminal no.) (R1.25-4) 40 20 39 (7.5) 40 20 Cable length (L) [m] 50.8 1 1.5 3 3 5 5 2 21 1 21 1 Pin no. Wire color Pin no. Wire color Pin no. Wire color Pin no.
28 Bore size With air cushion Air cushion type is not available for 21-/22-CJ2.
28 Bore size 11 11 10-0.022 0 12-0.027 0 With air cushion With air cushion type is not available for 21-/22-CJ2.
M14 x 2 11 200 2 128 15 M8 x 1.25 47 43.5 MY1C50 29 100 84.5 230 19 12.5 29.5 27.5 39.5 130 32 M16 x 2 13.5 230 5.5 152 16 M10 x 1.5 50 56 MY1C63 32.5 115 104 (mm) W1 NW PA PB PG Q PP QW QQ RR SS TT UU W WW Model NF NH VV XX Z 118 120 90 10 380 26 90 28 35 10 35 24 144 22 MY1C50 128 81 28 74 400 83.5 142 140 110 12 436 42 110 30 49 13 43 28 168 25 MY1C63 152 103 30 92 460 105 Y 2-d R WX
My Mp W W L2 B2 W C2: Correction value for moment center distance L1 A2 L3 C2 My (mm) A2: Correction value for moment center distance MXW 8 MXW12 MXW16 MXW20 MXW25 23 29 37 49 63 B2: Correction value for moment center distance (mm) Mr (mm) W Mp 10 10 14 20 28 W MXW 8 MXW12 MXW16 MXW20 MXW25 39 48 58 75 97 MXW 8 MXW12 MXW16 MXW20 MXW25 W Dynamic moment Moment due to impact of load at end
B2 LECSB2/Pulse input (Absolute encoder) 200 V to 230 V C2 LECSC2/CC-Link (Absolute encoder) 200 V to 230 V !
Sensor Range: 4 [For Positive Pressure (0~500kPa)], Port Size: 01 [R 1/8 (w/M5 Female Thread)], Output Specification: Voltage Output (1~5V) Type, Option: C2 [Connector for Pressure Sensor Controller (PSE300) 1 pc.]
Sensor Range: 4 [For Positive Pressure (0~500kPa)], Port Size: 01 [R 1/8 (w/M5 Female Thread)], Output Specification: Voltage Output (1~5V) Type, Option: C2 [Connector for Pressure Sensor Controller (PSE300) 1 pc.]
Mr My Mp W L2 B2 W W C2: Moment center position distance compensation amount My L1 A2 L3 C2 (mm) B2: Moment center position distance compensation amount MXW8 MXW12 MXW16 MXW20 MXW25 23 29 37 49 63 A2: Moment center position distance compensation amount Mr (mm) (mm) W Mp MXW8 MXW12 MXW16 MXW20 MXW25 39 48 58 75 97 MXW8 MXW12 MXW16 MXW20 MXW25 10 10 14 20 28 W W 8-7-2 3 Long Stroke Slide Table
K V 1 10 XLA S P1P2 XL XL Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2++1/Cn) when in series, and C=C1+C2++Cn, when in parallel.
Bore 1/32 1/16 1/8 1/4 3/8 1/2 3/4 1 1 6 15 37 1-1/8 5 12 28 85 1-1/2 3 7 16 50 2 4 9 28 70 2-1/2 6 18 45 72 3 4 12 30 48 3-1/4 3 10 24 37 79 4 7 17 28 60 5 4 11 18 40 82 6 3 7 12 26 55 8 4 7 15 32 10 4 9 20 12 3 6 14 NOTE: These values are an approximate speed, under average conditions, where the force required is 50% of available 80-100 PSI inlet pressure, the directional valve internal