Mechanically Jointed Rodless Cylinder with Brake, Hy-rodless Cylinder Series ML1C ø25, ø32, ø40 1

Calculate (1) (Wmax) from the graph of max. payload (W1, W2, W3) and calculate (2) and (3) (Mmax) from the maximum allowable moment graph (M1, M2, M3).

Thermo-chiller

+ 0.43 m2 0.37 m2 0.19 m2 965 mm 970 mm 500 mm 445 mm 377 mm 377 mm Globally compatible power supplies 50 Hz 60 Hz 50/60 Hz Power consumption reduced by 17% Energy saving 3-phase 200 VAC 3-phase 200 to 230 VAC 3-phase 380 to 415 VAC 3-phase 460 to 480 VAC Single-phase 200 to 230 VAC HRLE Series : HRLE090 : HRLE050 CAT.ES40-75A A Circulating Fluid Temperature Controller Thermo-chiller Compact

IZN10_C

IZN10 IZN10 IZN10 IZN10 01 01 01 01 P P P P 06 06 06 06 Z Z Z Z B1 B1 B1 B1 IZN10 AC 01 02 11 Rc1/8 NPN P PNP 06 6 07 6.351/4) 16 6 ( 17 6.351/4() (3m) Z (10m) N IZN10-NT L DIN IZN10A002 IZN10B1 L B2 B3 DIN 01 06 ES 2 01 ES 17mm 2 2 02 3 3 11 Rc1/8 4 4 /IZS30 /IZS30 /IZS30 /IZS30-M2 M2 M2 M2 06 6: 07 6.351/4: 16 6 :( 17 6.35(1/4):() IZN10-CP(3m) IZN10-CPZ(10m) IZN10A003 NPN

180

= d x e x f x Specific gravity m2 = 5 x 10 x 12 x 2.7 x 10-6 = 0.002 (kg) Moment of inertia around Z2 axis IZ2 = {m2 (d2 + e2)/12} x 10-6 IZ2 = {0.002 x (52 + 102)/12} x 10-6 = 0.02 x 10-6 (kgm2) IB = 0.02 x 10-6 + 0.002 x 472 x 10-6 = 4.4 x 10-6 (kgm2) I = 9.0 x 10-6 + 4.4 x 10-6 = 13.4 x 10-6= 0.13 x 10-4 (kgm2) Moment of inertia around Z axis IB = IZ2 + m2r22 x 10-6 Total moment of

180
Angular Style Air Gripper Series MHY2/MHW2 Cam Style Rack & Pinion Style 1

= d x e x f x Specific gravity m2 = 5 x 10 x 12 x 2.7 x 10-6 = 0.002 (kg) Moment of inertia around Z2 axis IZ2 = {m2 (d2 + e2)/12} x 10-6 IZ2 = {0.002 x (52 + 102)/12} x 10-6 = 0.02 x 10-6 (kgm2) IB = 0.02 x 10-6 + 0.002 x 472 x 10-6 = 4.4 x 10-6 (kgm2) I = 9.0 x 10-6 + 4.4 x 10-6 = 13.4 x 10-6= 0.13 x 10-4 (kgm2) Moment of inertia around Z axis IB = IZ2 + m2r22 x 10-6 Total moment of

Mechanically Jointed Rodless Cylinder with Brake, Hy-rodless Cylinder Series ML1C ø25, ø32, ø40 1

Calculate (1) (Wmax) from the graph of max. payload (W1, W2, W3) and calculate (2) and (3) (Mmax) from the maximum allowable moment graph (M1, M2, M3).

ML1C

Moment (Nm) Moment (Nm) Moment (Nm) Load mass (kg) M1 = F1 x L1 Piston speed V (mm/s) ML1C/M2, M3 M2 = F2 x L2 M3 = F3 x L3 Piston speed V (mm/s) (How to calculate the load ratio) A. Consider (1) max. load mass, (2) static moment, (3) dynamic moment (when stopper collides) when calculating the max. allowable moment and load mass.

180
Angular Style Air Gripper Series MHY2/MHW2 Cam Style Rack & Pinion Style 1

= d x e x f x Specific gravity m2 = 5 x 10 x 12 x 2.7 x 10-6 = 0.002 (kg) Moment of inertia around Z2 axis IZ2 = {m2 (d2 + e2)/12} x 10-6 IZ2 = {0.002 x (52 + 102)/12} x 10-6 = 0.02 x 10-6 (kgm2) IB = 0.02 x 10-6 + 0.002 x 472 x 10-6 = 4.4 x 10-6 (kgm2) I = 9.0 x 10-6 + 4.4 x 10-6 = 13.4 x 10-6= 0.13 x 10-4 (kgm2) Moment of inertia around Z axis IB = IZ2 + m2r22 x 10-6 Total moment of

MHY2/MHW2

2.7 X 10-6 Calculation of weight m2 = d X e X f X Specific gravity = 0.002(kg) Iz2 = {0.002 X (52 + 102)/12} X 10-6 Moment of inertia around Z2 axis = 0.02 X 10-6 (kgm 2) IB = 0.02 X 10-6 + 0.002 X 472 X 10-6 Iz2 = {m2(d 2 + e2)/12} x 10-6 Moment of inertia around Z axis IB = IZ2 + m2r22 x 10-6 = 4.4 X 10-6 (kgm2) I = 9.0 X 10-6 + 4.4 X 10-6 Total moment of inertia I = IA + IB = 13.4 X

F

U N I O N Y KQU (KQ2U) Applicable Model D1 D2 L1 L2 P Q M1 M2 Effective Orifice Tube OD mm (mm2) a b Nylon/Urethane 3.2 4 KQU23-04 9.6 10.4 33.5 17.5 9.6 9 15.5 16 3.2/2.7 4 6 KQU04-06 10.4 12.8 35 18 10.4 9.7 16 17 4.2/4.2 6 8 KQU06-08 12.8 15.2 39.5 20 12.8 11.7 17 18.5 13.4/13.4 8 10 KQU08-10 15.2 18.5 45 24.5 15.2 13.7 18.5 21 25.6/17.7 10 12 KQU10-12 18.5 20.9 49 27.5 18.5 16.1 21 22

Stainless Steel One-touch Fittings Series KG

(mm) I Weight (g) Nylon Urethane M1 D1 D2 L1 Q L2 P M2 Part No. 9.7 11.7 8 6 35.5 40.5 6 4 KGUD06-08 KGUD04-06 10.4 18.2 16 12.8 20.3 17 12.8 15.2 10.4 12.8 21 26 17 18.5 4.2 13.4 4.2 13.4 11 19 Plug-in reducer: KGR Effective orifice(mm 2) Applicable tube O.D. (mm) Applicable fitting size d Part No.

Uniaxial Electric Actuator Series LJ1

acceleration (mm/s) Mounting position Direction of load movement Model LJ1H10 LJ1H20 LJ1H30 Horizontal/Lateral Horizontal/Lateral Vertical Lateral Horizontal a M1 2000 a=1000 a=1000 2000 2000 a=1000 L1 mm L1 mm L1 mm Pitching W a=2000 a=2000 a=3000 a=3000 a=2000 1000 1000 1000 L1 a=3000 0 2 4 6 8 10 0 10 20 30 0 20 40 60 Work load (W) kg Work load (W) kg Work load (W) kg 600 600 600 L2 M2

Series KG Stainless Steel One-touch Fittings

(mm) I Weight (g) Nylon Urethane M1 D1 D2 L1 Q L2 P M2 Part No. 9.7 11.7 8 6 35.5 40.5 6 4 KGUD06-08 KGUD04-06 10.4 18.2 16 12.8 20.3 17 12.8 15.2 10.4 12.8 21 26 17 18.5 4.2 13.4 4.2 13.4 11 19 Plug-in reducer: KGR Effective orifice(mm 2) Applicable tube O.D. (mm) Applicable fitting size d Part No.

VDW

PA PAX PB Flow Characteristics Water Air Orifice size (mm ) Port size Av x 10-6 m2 12 (INN.C.) 13 (INN.O.) 12 (INN.C.) 13 (INN.O.) Model C [dm3/(sbar)] C [dm3/(sbar)] Av x 10-6 m2 Cv converted Cv converted b Cv b Cv N.O.

VXD21/22/23

IN Model/Valve Specifications Max. operating pressure differential (MPa) Connection Weight (g) Av x 10-6 (m2) Cv converted C [dm 3/(sbar)] b Cv Water, Oil Air Flow characteristics Min. operating pressure differential (MPa) Orifice size (mm) Model Air Water Thread Oil AC DC AC DC AC DC 0.7 0.7 1.0 0.7 1.0 1.0 Max. system pressure (MPa) 1 4 1.9 2.4 4.5 2.4 5.5 9.5 VXD2130-

ZR

.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com Components Valve unit + Ejector unit Individual, common and port exhaust style for nozzle size 10, 13 Common and port exhaust style for nozzle size 15 Individual exhaust style for nozzle size 15 M2 x 0.4 x 13 2 2 2 2 2 2 2 4 4 M2 x 0.4 x 23 M2 x 0.4 x

CL

CL Ek: Kinetic energy of load (J) m: Load weight (kg) : Piston speed (m/s) (Average speed x 1.2 times) Ek = m2 1 2 CL1 3. The piston speed will exceed the average speed immediately before locking. To determine the piston speed for the purpose of obtaining the kinetic energy of load, use 1.2 times the average speed as a guide. 4.

Escapements Series MIW/MIS ø8, ø12, ø20, ø25, ø32 1

Mount the cover and tighten the hexagon socket head screws with the tightening torque in the table below. 1.5 J DScraper mounting thread -X 20Data Scraper Hexagon socket head screw Hexagon width across flats Tightening torque (Nm) Bore size Scraper mounting thread 8 12 20 25 32 0.24 1.5 M2 x 6 0.36 2 M2.5 x 6 1.5 3 M4 x 10 3.0 4 M5 x 14 Scraper 5.2 5 M6 x 15 10-11-19

CL

CL Ek: Kinetic energy of load (J) m: Load weight (kg) : Piston speed (m/s) (Average speed x 1.2 times) Ek = m2 1 2 CL1 3. The piston speed will exceed the average speed immediately before locking. To determine the piston speed for the purpose of obtaining the kinetic energy of load, use 1.2 times the average speed as a guide. 4.

0.5

IZF 21 IZF 31 P.12 Emitter cartridge drop prevention Related equipment P.12 Cleaning kit IZS30-M2 Emitter cartridge retaining screw M3 x 12 1 pc. (Provided by customer) Emitter cartridge Emitter cartridge 3 Fan Type Ionizer IZF Series M Flow Rate Adjustment Function IZF 10R IZF 21 IZF 31 Flow rate is adjustable in 10 steps* using the flow rate adjustment dial.