ChemicalThermo-con : 95F (35C) Facility water: 95F (35C) 400 400 200 0 0 0 10 20 30 40 50 60 70 Circulating fluid temperature (C) 0 10 20 30 40 50 60 70 Circulating fluid temperature (C) HED007 60 80 100 120 140 F 40 1600 Facility water: 50F (10C) Facility water: 77F (25C) Cooling capacity (W) 1200 Facility water: 95F (35C) 800 400 0 0 10 20 30 40 50 60 70 Circulating fluid temperature (C) Heating Capacity
MY2 H/HT MY3A MY3B MY3M Load Mass Allowable Moment MY1H/m3 MY1H/M3 MY1H/M1 MY1H/M2 q r w e t 30 40 50 50 40 30 40 50 30 40 50 30 20 20 20 20 MY1H40 MY1H32 10 10 10 MY1H40 MY1H40 MY1H32 Load mass kg MY1H32 Moment Nm Moment Nm Moment Nm 5 4 3 MY1H25 MY1H40 10 5 4 3 5 4 3 MY1H32 MY1H25 MY1H25 2 MY1H25 5 4 2 2 1 3 1 1 0.5 0.4 0.3 2 0.5 0.4 0.3 0.5 0.4 0.3 D0.2 1 0.2 0.2 0.1 -X 100 200 300 400
Y 0: 2_P (Normal output) 1: 2_n (Reverse output) 1540 0x0604 0 R/W Dir (Setting of the accumulated flow direction) 0: Add 1: dEC1 2: dEC2 Addition/Subtraction U8 0 Y 1600 0x0640 0 R/W 0: 1.0 sec 1: 2.0 sec 2: 5.0 sec 1 R/W FiL_FLoW (Digital filter_flow rate) U8 0 Y Set digital filter 1800 0x0708 2 R/W FiL_PrES (Digital filter_pressure) U16 10 Y 0 to 3000 ms 10 ms increments (0 to 30 sec.)
MK2B25-10 MK2B25-20 MK2B32-10 MK2B32-20 MK2B40-10 MK2B40-20 MK2B50-20 MK2B50-50 MK2B63-20 MK2B63-50 8.5 To attach and detach the arm to and from the piston rod, fix the arm with a wrench or vise and then tighten the bolt.
-(BJM) . 9-5 9.3.2 HRS060-W-20-(BJM) . 9-6 9.4 Cooling capacity . 9-7 9.4.1 HRS060--20-(BJM) . 9-7 9.5 Heating capacity . 9-7 9.5.1 HRS060-A-20-(BJM) . 9-7 9.5.2 HRS060-W-20-(BJM) . 9-7 9.6 Pump capacity. 9-8 9.6.1 HRS060--20-(BJM) . 9-8 9.7 Required facility water flow (For water-cooled type) . 9-8 9.8 Compliance . 9-9 HRS Series HRX-OM-R005 Contents 9.9 Sample DoC. . 9-10 9.10 Daily Check
12 CUJ A B W CU 16/20/25 CQS CQM W A B CQ2 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 RQ Hs 32/40/50 MU D(mm) -X D-A9 D-M9 D-F9 W Auto switch model D-F9BAL Mounting height Hs exists only for the D-F9BAL type. 20Symbol A B W A B W A B W HS 16.5 18.5 22 24 26.5
Refer to pages 6-20-3 to 6-20-6 for Safety Instructions and Actuator Precautions.
AMK Series Construction Size 20 to 40 q w OUT IN t Component Parts e No.
X axis Y axis Z axis Z 5 W 5 mm 10 mm 20 mm 0.8 kg 20 Y 10 3.
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.
moment Static moment L2 A3 W MXH Mp Mr My MXU W W W MXS L1 A2 L3 A6 W L2 A4 MXQ Mey Note) No need to consider this load factor in the case of using perpendicularly in a vertical position.
RSH REC20 20 Front flange: F Rear flange: G 39 50 56 61 0.3 Foot: L L CE1 10 30 38 43 47 0.5 W W W CE2 F 5 24 31 36 39 0.7 11 17 19 21 0.3 ML2B 7 11 13 13 G 0.5 ML1C 1 10 50 100 200 300400 Max. speed u (mm/s) (Initial cushioning speed) 4 7 9 9 0.7 500 REA Front trunnion: U Rear trunnion: T 32 42 48 52 0.3 Clevis: C, D C 22 30 35 37 0.5 REC Graph w Applicable max. stroke against lateral load
resred lIr) flor. l{rn/rytle (lloloq l{0. tt odell OEtl l ,5lllx l 20 25.0 0.3.3.J 260 126,000 t3,000 19 58 2,890 0.9 lR0tl.5lltxl 20 25.0 0.08-t.3 260 t26,000 13,000 49 68 6,660 0.9 Offll.5Xtx2 20 50.0 0.3-3.5 520 167.000 t3,000 JI 68 2,890 1.0 tR0tXll.5ltlx2 20 50.0 0.08-1.3 520 1o,000 r3,000 49 80 6,660 L0 0tlSl.5flr3 20 75.0 0.3-3.5 7S0 201,000 ,000 32 80 2,890 1.2 0IIlt2.0tltx2 30 50.0
Load Mass Allowable Moment MY2H/m3 MY2H/M3 MY2H/M1 MY2H/M2 q r w e t 60 50 60 50 60 50 60 50 40 40 30 30 30 30 20 20 20 20 Load mass kg Moment Nm Moment Nm Moment Nm MY2H40 MY2H40 MY2H40 MY2H40 10 10 10 10 MY2H25 MY2H25 MY2H25 MY2H25 5 5 5 5 4 4 4 4 D3 3 3 3 MY2H16 -X 2 2 2 2 0.2 MY2H16 MY2H16 Individual -X MY2H16 1 1 1 100 200 300 400500 1000 1500 1 100 200 300400 500 1000 1500 100 200 300
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.
GR GQ H1 I 18 13 38 93 1/8 56.5 14 8 12 2 85 10 18 5.5 6 4 8 5 26 20 to 200 15.5 to 200 22 17 45 103 1/8 66 16.5 10 14 2 96 10 25 6.5 9 7 10 6 31 20 to 300 19.5 to 300 22 17 45 104 1/8 67.5 20 12 18 2 97 10 25 6.5 9 7 10 6 38 20 to 300 19.5 to 300 30 19 52 112 1/8 75 26 16 25 2 104 10 (13) 26 7 11 7 12 8 47 20 to 300 301 to 500 301 to 500 27 to 300 (mm) Bore size (mm) 20 25 32 40 P
Load Mass Allowable Moment E-MY2H/M1 E-MY2H/M3 E-MY2H/M2 E-MY2H/m3 60 60 50 60 60 50 50 50 40 40 30 30 30 30 q r w et 20 20 20 20 Load Mass (kg) Moment (NNm) Moment (NNm) Moment (NNm) 10 10 10 10 MY2H25 MY2H25 MY2H25 MY2H25 5 5 5 5 MY2H16 4 4 4 4 3 3 3 3 MY2H16 MY2H16 2 2 2 2 MY2H16 0.2 1 1 1 100 200 300 400 500 1000 1500 1 100 200 300 400 500 1000 1500 100 200 300 400 500 1000 1500 100 200
l b --" ,m'i$;:f, 4ra 20 Standard Stroke lmm) 30 40 50 60 75 100 125 175 200 225 250 275 300 350 400 150 Y f r N t * w -l Yw Y Ns a a a a a a a a a a a a a o a a a a a a a a a a a a a a a a a '*?
Model determination 61 Series REBR Model Selection 2 Design Parameters 1 Selection Method REBR25 REBR32 REBR15 500 400 300 200 300 200 Allowable driving force Fn (N) Load weight W (kg) Allowable driving force Fn (N) Allowable driving force Fn (N) 50 100 100 40 30 40 50 20 30 40 50 30 20 20 Usable range 10 10 10 Usable