LEYx-OMZ0015 Note 7) For an actuator with lock, add the power consumption for the lock. -7- Model LEY100L LEY100D LEY100B Stroke[mm] Note 1) 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000 Work load [kg] Horizontal Note 2) 1,200 1,200 240 Vertical 200 185 80 Force [N] Note3,4) 25 to 55% 5,500 3,300 1,100 ~12,000 ~7,200 ~2,600 To 500 100 167 500 500 to 600 74 123 370 Maximum Speed [mm/s] Note 5) Range
Thread type Nil F N T Rc G NPT NPTF Rated voltage DC AC (50/60 Hz) 5 6 V S R 1 2 3 4 24 VDC 12 VDC 6 VDC 5 VDC 3 VDC 100 VAC 200 VAC 110 VAC [115 VAC] 220 VAC [230 VAC] A, B port size 01 C6 C8 N7 N9 1/8 One-touch fitting for 6 One-touch fitting for 8 Note) Do not remove the factory installed bracket from models with the bracket option.
MXP16-30 Table displacement amount (mm) Table displacement amount (mm) Table displacement amount (mm) 0.08 0.12 0.06 MXP16-20 MXP16-30 MXP16-20 MXP16-30 MXP16-20 MXP16-30 MXP16-20 MXP16-30 0.10 0.06 0.04 0.08 0.04 0.06 0.04 0.02 0.02 0.02 0 0 0 50 200 250 Load (N) 150 100 50 200 250 Load (N) 150 100 100 400 500 Load (N) 300 200 196 Air Slide Table Series MXP Table Accuracy Non-rotating accuracy
3 35 x 31 x 2 28 x 25 x 1.5 O-ring NBR i How to order (1) When adding n stations to ARM Regulator n pcs. Bracket assembly n pcs. (2) When regulators, end plate assembly and bracket assembly are assembled to make the manifold of n stations. Regulator n pcs. Bracket assembly n pcs.
3 35 x 31 x 2 28 x 25 x 1.5 O-ring NBR i How to order (1) When adding n stations to ARM Regulator n pcs. Bracket assembly n pcs. (2) When regulators, end plate assembly and bracket assembly are assembled to make the manifold of n stations. Regulator n pcs. Bracket assembly n pcs.
Recommended shim thickness) Arm length L: 6 in 0.04 0.02 0.06 500 Clamping force (lbf) 400 0.7 MPa 300 0.5 MPa 0.3 MPa 200 100 0 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 Shim thickness (in) 186 Model Selection 2 Slim-line power clamp cylinder mounting 63 Arm length L: 200 mm 4000 Clamping force (N) 3000 CK1 CLK2 C(L)KQ MK2T/MK2/MK CKZ2N CKZT CLKZ1R CK/M(D)UKA 2000 1000 0 0 1 2 3 4 5 6 7 8 9 Shim
(page 79) 8010 0x1F4A 0 R Flow rate PD intercept b F32 N The conversion method from the communication value to the actual measurement value is the same as the method for process data. 8030 0x1F5E 0 R Flow bottom value S16 0 N 8020 0x1F54 0 R Flow peak value S16 0 N -200 to 4200 1 R Accumulated mantissa F32 N 0 to 9 Accumulated PD Accumulated value conversion factor = Current accumulated
+ 40 (n 4) 2 90 + 40 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 15 + 40 n (n = 2, 4, 6, 8 ) Note 1) (n = 4, 8, 12, 16 ) Note 2) 2 (Different surfaces, Same surface) 1 55 60 65 D-A9V (n 2) 2 10 50 50 + 30 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 55 + 30 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 60 + 30 (n 4) 2 65 + 30 (n 4) 2 (n = 4, 8, 12, 16 ) Note 2) 10 + 30 n (n = 2, 4, 6, 8 ) Note 1) (n = 4, 8,
-A22 ZPT125 50-(B/N/T)01-A22 ZPT125 75-(B/N/T)01-A22 ZPT125 100-(B/N/T)01-A22 ZPB-T1 25-(B/N/T)01 ZPB-T1 50-(B/N/T)01 ZPB-T1 75-(B/N/T)01 ZPB-T1 25-(B/N/T)01 ZPB-T1 50-(B/N/T)01 ZPB-T1 75-(B/N/T)01 ZPB-T2 25-(B/N/T)01 ZPB-T2 50-(B/N/T)01 ZPB-T2 75-(B/N/T)01 ZPB-T2 25-(B/N/T)01 ZPB-T2 50-(B/N/T)01 ZPB-T2 75-(B/N/T)01 ZPB-T3 25-(B/N/T)01 ZPB-T3 50-(B/N/T)01 ZPB-T3 75-(B/N/T)01 ZPB-T3 100-(B
Angle adjusting screw Angle adjusting screw Angle adjusting screw n o A R ti n 0 0 n c ot g 9 e 9 o l e y at ir ti y c d a a a io e d w g w ir n j n u y d y ti s ra e e g s ti k k u n n n g j ti of d g of s d a e u ir e e e e j d of c l g a g ti g o n n e n k A n l g n ra ra A e y n n w io io a y at at 9 ot ot 0 R R The rotation range under the adjustment of an angle at 60 is indicated
VF VFR How to Order Valve Manifold Assembly (Example) VP7 VP4 VQZ2150-5L VQZ2250-5L VQ U side 2 3 4 5 VQZ2350-5L VQ4 VV5QZ2505C6C1 set (C kit 5 stations manifold base) VVQZ200010A-51 set (Blank plate assembly) VQZ21505L 1 set (Valve P/N single solenoid) VQZ22505L 2 set (Valve P/N double solenoid) VQZ23505L 1 set (Valve P/N 3 position) VQZ D side 1 VQD VZS Prefix mark to valves etc. to
Model determination 2 Sine Rodless Cylinder Series REA Model Selection Method 2 Precautions on Design 1 Selection Method 40 32 25 500 500 300 200 300 400 Recommended driving force: Fn(N) 200 300 Recommended driving force: Fn(N) Recommended driving force: Fn(N) 200 100 100 100 50 40 20 30 40 50 20 30 40 50 20 30 Usable
(7) n SW1 CN1A 9 (9) SW2 (8) CN1B 2 1 3 7 3 1.
x 0.8 (A port) 5 15 P = 10 38 n: Stations (Maximum 18 stations) Formula: L1 = 10n + 32 L2 = 10n + 43 Dimensions n L 2 3 4 5 6 7 8 9 10 L1 L2 (L3) (L4) (L5) 11 12 13 14 15 16 17 18 52 63 83 112.5 123 62 73 93 112.5 123 72 83 103 125 135.5 82 93 113 137.5 148 92 103 123 150 160.5 102 113 133 162.5 173 112 123 143 162.5 173 122 133 153 175 185.5 132 143 163 187.5 198 142 153 173 200 210.5 152
L N Electrical entry U Option Note) Except latching and large flow type.
L N Electrical entry U Option Note) Except latching and large flow type.
Long Stroke Stroke range (mm) Y X Z Bore size (mm) 12 50, 75, 100 32 7.5 7.5 16 50, 75, 100 32 7.5 7.5 20 75, 100, 125, 150, 175, 200 41 9 9 25 75, 100, 125, 150, 175, 200, 250, 300 44 11 11 8-27-8 9 Platform Cylinder Series CXT Dimensions: 32, 40 (N) X + Stroke S + Stroke H 4-M8 x 1.25 4-8.7 through, counterbore 14 depth 8 HP Depth 12 HG 12 Back side 4-M10 x 1.5 depth 15 (N) T PA T MX d
390 N 490 N 588 N 245 N 390 N 490 N 588 N Allowable radial load Shaft load MSU 196 N 340 N 490 N 539 N 196 N 340 N 490 N 539 N Allowable thrust load Bearing Bearing CRJ Side ported or Axial ported Port location Rc 1/8 Rc 1/4 Rc 1/8 Rc 1/4 Side ported CRA1 Size Rc 1/8 Rc 1/4 Rc 1/8 Rc 1/4 Axial ported CRQ2 Mounting Basic style, Foot style Size: 80 Size: 100 MSQ Volume MRQ (cm 3) Size: 50 Rotating
490 N 390 N 245 N 588 N 390 N 490 N 245 N Allowable radial load Shaft load MSU 539 N 490 N 340 N 196 N 539 N 340 N 490 N 196 N Allowable thrust load Bearing Bearing CRJ 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 Side ported or Axial ported Port location Rc 1/
Dimensions Formula: L1 = 41n + 76, L2 = 41n + 96 n: Stations (Maximum 12 stations) Formula: L1 = 41n + 76, L2 = 41n + 96 n: Stations (Maximum 12 stations) L n Dimensions 2 158 178 9 445 465 2 158 178 9 445 465 3 199 219 10 486 506 3 199 219 10 486 506 4 240 260 11 527 547 4 240 260 11 527 547 5 281 301 12 568 588 5 281 301 12 568 588 6 322 342 6 322 342 7 363 383 7 363 383 8 404 424 L1 L2