20 OFENERGYSAVINGEFFECTS 10% reduction s"LOWINGDISTANCEMM #OSTOFELECTRICITYCONSUMEDBY COMPRESSORHUNDREDOF ) s)MPACTPRESSURE-0A 154 /year s#OSTOFELECTRICITY /kWh Work model Conventional model s"LOWTIMESECONDS 1388 s&REQUENCYTIMESHOUR s7ORKINGHOURSHOURSDAY "LOWGUNONLY s7ORKINGDAYSDAYSYEAR s5NITSUSED HOURS s2ESULTINGTOTALWORKINGHOURS HOURS 850 4OTALWORKINGHOURSOFUSE Valve Construction
W is width across flats dimension. Connection threads NPT Model L H A M W E Applicable tubing O.D.
(rad/s) : Rotation angle.(rad) 180 = 3.14rad t: Rotation time.
Note 3) ( ) in column W is the dimensions of D-A93.
@w, s Bore Siee Noaulo swjtch builtjn (hjglr magnelic Add L and Z at the end of part numberlor 3m and sfi, respectively. "ALrto switch detail: see pgs. 10-11.
Vacuum pressure Theoretical lifting force Horizontal lifting force [N]Safety factor 1/4 [kPa] [N] 1 cup gripping -50 40.2 10 2 cups gripping -67 53.8 13.4 3 cups gripping -73 58.7 14.6 (Calculated by W = P X S, S = r2, r = 32 / 2. Refer to 3.3 How to calculate theoretical lifting force for the detail.)
Vacuum pressure Theoretical lifting force Horizontal lifting force [N]Safety factor 1/4 [kPa] [N] 1 cup gripping -50 40.2 10.0 2 cups gripping -67 53.8 13.4 3 cups gripping -73 58.7 14.6 (Calculated by W = P X S, S = r2, r = 32 / 2. Refer to 3.3 How to calculate theoretical lifting force for the detail.)
Vacuum pressure Theoretical lifting force Horizontal lifting force [N]Safety factor 1/4 [kPa] [N] 1 cup gripping -50 40.2 10.0 2 cups gripping -67 53.8 13.4 3 cups gripping -73 58.7 14.6 (Calculated by W = P X S, S = r2, r = 32 / 2. Refer to 3.3 How to calculate theoretical lifting force for the detail.)
Vacuum pressure Theoretical lifting force Horizontal lifting force [N]Safety factor 1/4 [kPa] [N] 1 cup gripping -50 40.2 10 2 cups gripping -67 53.8 13.4 3 cups gripping -73 58.7 14.6 (Calculated by W = P X S, S = r2, r = 32 / 2. Refer to 3.3 How to calculate theoretical lifting force for the detail.)
TQ1230001-OM102-B
M CQS J79W S B 25 10 S M MDU With auto switch CQM CQ2 Built-in magnet Number of auto switches Mounting style RQ Nil S n 2 pcs. 1 pc. n pcs.
M CQS J79W S B 25 10 S M MDU With auto switch CQM CQ2 Built-in magnet 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 Number of auto switches Mounting style RQ Nil S n 2 pcs. 1 pc. n pcs.
Rotate the lever assembly w to align the holes on the lever assembly w and the base e. Insert the lever pin q into the holes to fix the lever assembly w. 1 y Tubing !1 Holder assembly replacement screw i Holder assembly r Insert pin assembly u Fitting nut Place the insert bushing t on the insert pin assembly r. t Insert bushing 2 !
Example: Set 20 W (100 W 20%) for the 100-W external Regenerative resistor with natural convection cooling method: Pn600 = 2 (unit: 10 W) Note 1. If Pn600 is not set to the optimum value, alarm A.320 will occur. 2.
Example: Set 20 W (100 W 20%) for the 100-W external Regenerative resistor with natural convection cooling method: Pn600 = 2 (unit: 10 W) Note 1. If Pn600 is not set to the optimum value, alarm A.320 will occur . 2.
Tank capacity (l) Tc [s] = L W Obtain the tank capacity V. Select tank from table below.
Compact Rotary Actuator Rack & Pinion Style Series CRQ2 How to Order CRQ2B S 20 90 Without auto switch CDRQ2B S 20 90 M9BW With auto switch Built-in magnet Number of auto switches Shaft type S W Single shaft Double shaft 2 pcs. 1 pc. n pcs. Nil S n Refer to pages 254 and 255 for the shaft type variations.