Mechanically Jointed Rodless Cylinder MY1H Series Linear Guide Type: ø25, ø32, ø40  Piping can be connected from 4 directions on the head cover.  Allows on-site piping to suit the MY1B installation MY1H MY1H conditions. MY1B MY1M MY1C MY

Cushion needle Q + Stroke PG MY1B P P (MY1HG) MY1H MY1H (Hexagon socket head taper plug) 1 (Hexagon socket head taper plug) QQ SS RR YH MY1B PP QQ RR SS A B H NE NH NF MY1M P P (MY1HG) P (Port) P (Port) PP (Hexagon socket head taper plug) (Hexagon socket head taper plug) G G MY1C TTT UU UU TT A N Z + Stroke MY1H P MY1 HT P (Port) (Hexagon socket head taper plug) MY1 W MY2C P P (Port) (Hexagon

3 Port Solenoid Valve

Single r w u e y i q !

ZQ

) S R U N L H L H k P a MOD E SET HYS Air supply port (P port) Note 4) (M3 x 0.5, piping not required) 71.9 66.9 (63.1) (M5 x 0.8) 57.3 Vacuum port (V port) Note 4) 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 PE SMC (M5 x 0.8) 29.4 3 20.2 P 20.3 9.7 V Exhaust

energy saving effect

V: Power supply voltage Power consumption P: 20 [kW] Q = P = 20 [kW] P Cooling capacity = Considering a safety factor of 20%, 20 [kW] x 1.2 = 24 [kW] Power consumption w Derive the heat generation amount from the power e Derive the heat generation amount from the output. supply output. Output (shaft power etc.)

High Purity Fluoropolymer

Metric size Inch size 1/4" 3/8" 1/8" 1/2" 3/4" 6 8 10 12 19 3/16" 1/8" 1/4" 3/8" 1/2" 3/4" 4 None 2 3 Male 4 P.21 Connector LQ2H 5 2 3 Female 4 P.22 5 2 3 Male 4 P.23 Elbow LQ2L 5 2 3 Female 4 P.24 5 2 3 Male 4 P.25 Run tee LQ2R 5 2 3 Female 4 P.26 5 2 3 Male 4 P.27 Branch tee LQ2B 5 2 3 Female 4 P.28 5 2 3 Union elbow LQ2E 4 P.29 5 2 Union tee LQ2T 3 4 P.29 5 Features 4 Series LQ1 ,TL/TIL

Large Size Vacuum Module: Series ZR

Example) ZR1--CN(-Q) . 1 pc. ZS-10-5A-50 . 1 pc.

Thermo-chiller

V: Power supply voltage Power consumption P: 7 [kW] Q = P = 7 [kW] P Cooling capacity = Considering a safety factor of 20%, 7 [kW] x 1.2 = 8.4 [kW] Power consumption w Derive the heat generation amount from the power e Derive the heat generation amount from the output. supply output. Output (shaft power etc.)

3-Screen Display Multi-channel Digital Sensor Monitor Up to 4 pressure sensors can be connected!

Circuits and Wiring Examples p. 9 Options/Part Nos.

V

48.5 63.6 25 89.5 79.5 10 15 ZPR40D 40 43 29 42.5 53.3 71.1 25 97 87 17 15 A P P L I C A B L E T U B E A P P L I C A B L E T U B E Applicable Tube OD P Q R S Applicable Tube OD P Q R S 4 4 23.3 15.8 10.4 6 6 24.3 16.8 12.8 H O W T O O R D E R Z P R P A D H O R I Z O N T A L T Y P E W I T H O U T B U F F E R 6 6 24.3 16.8 12.8 8 8 26.2 18.7 15.2 8 8 26.2 18.7 15.2 ZPR P A D D I A M E T E

Series VS

Wiring & Light / Surge Voltage Suppressor How to calculate Flow (At an air temperature 20C) AC AND 100 VDC AC AND 100 VDC WITH LIGHT WITH LIGHT TERMINAL no.1 (+) TERMINAL no.1 (+) Subsonic flow: P1+0.1013<1.89(P2+0.1013) SINGLE SINGLE Q=226S P(P2+0.1013) Sonic flow: P1+0.1013>1.89(P2+0.1013) ZNR ZNR Q=113S(P1+0.1013) Q: Flow rate under standard conditions [l/min(ANR)] S: Effective area (mm2

VQ7-6/7-8

How to Find the Flow Rate (at air temperature of 20C) Subsonic flow when P1 + 0.1013 < 1.89 (P2 + 0.1013) Q = 226S P(P2 + 0.1013) Sonic flow when P1 + 0.1013 1.89 (P2 + 0.1013) Q = 113S (P1 + 0.1013) Q: Air flow rate [l/min (ANR)] S: Effective area (mm) P: Differential pressure (P1-P2) [MPa] P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] Correction for different air temperatures

Fieldbus system EtherNet/IP TM compatible SI Unit IO-Link Master Unit

IOL_Autostart DI_C/Q Digital input only. DO_C/Q Digital output only. -75No.EX-OMX1011 IO-Link master unit parameters (continued) No.

Filter for Cleaning Solvent Quick Change Filter Series FQ1

Element symbol L125 L250 L500 Cleaning level Name Material (Nominal) 5 0.5 Series FQ1010 Series FQ1011 Series FQ1012 15 1 PP Q EHM ... x 3 5 Consult P/A if the number of elements calculated in exceeds two.

5 Port Solenoid Valve/Body Ported, Cassette Type Manifold, Series SZ3000

Example of how to order a valve SZ Q TUV approved product Enter the standard part number Example of how to order a manifold SS5Z Q TUV approved product Enter the standard part number Note) Contact P/A for details, as there are limitations on product models, voltage specifications and electrical entry, etc.

Environment

How to Order S 2 B P H S4 200 LEY 63 A2 w y !0 i o e r t q u !1 !2 !3 !

53

V: Power supply voltage HRSH 090 HRSH 090 Power consumption P: 7 [kW] Q = P = 7 [kW] P HRSH Cooling capacity = Considering a safety factor of 20%, 7 [kW] x 1.2 = 8.4 [kW] Power consumption HRSE w Derive the heat generation amount from the power e Derive the heat generation amount from the output. HRZ supply output. Output (shaft power etc.)

Lightweight and Compact

V: Power supply voltage Power consumption P: 7 [kW] Q = P = 7 [kW] P Cooling capacity = Considering a safety factor of 20%, 7 [kW] x 1.2 = 8.4 [kW] Power consumption w Derive the heat generation amount from the power e Derive the heat generation amount from the output. supply output. Output (shaft power etc.)

MY1

(Refer to P. 1365.)

Slider Type/Ball Bushing Bearing

Note 2) Determination of pressure (P) when making intermediate stop P Ps P > Ps (Refer to page 1529.) (For intermediate stops, refer to page 1527.)

High Vacuum Angle Valve, XL Series

XLGV/With solenoid valve Q Port R (exhaust port) N N With double solenoid P K M L (mm) L 6.5 6.5 6.5 11 11 11 K 9 9 9 11 11 11 N 14 Model K L M N P Q M 17 15 2 6 Q 16.5 16.5 17.5 28 29 29 P Model XLGV-16 XLGV-25 XLGV-40 XLGV-50 XLGV-63 XLGV-80 3 3 3 6.5 6.5 6.5 16 With single solenoid Port P (pressure port) 29 26 32 45 Other dimensions are the same as XLG. 19 Series XLD, XLDV Smooth Exhaust