NAMUR Interface 3 Port Solenoid Valve VFN200N Series [Option] VFN212N-5D-02F 240 VFN212N-5D-02F-D 380 C b Cv C b Cv 2-position Single solenoid 2.68 0.40 0.72 5.41 0.31 1.38 Double solenoid 2.68 0.40 0.72 5.41 0.31 1.38 189 A VFN200N Series Dimensions DIN terminal VFN212N-l D (Y)ll-02l-l 138 19 23 Applicable heavy-duty cord O.D. 6 to 8 Pg 9 Indicator light (With "Z") 84.5 ( Without "Z": 66.5) 36.5 75.5 (Without "Z": 57) 2(A) port 24 32 40 119 Pilot EXH 14
Body size 2 AMC220 AMC310, 320 AMC510, 520 AMC610 AMC810 AMC910 Refer to page 5-10-14 for Specific Product Precautions. 3 5 6 8 9 Model/Male Thread Type Model Specifications Effective area (mm2) AMC310 AMC510 AMC610 AMC810 AMC910 16 55 165 330 550 Max. air flow (l/min(ANR)) Port size Weight (kg) Element model no.
FlowRateandEffectiveArea FlowDirection SymbolonBody AS1002F 3.2,4,6 1/8",5/32" 1/4" 100 1.5 AS2002F 4 AS3002F AS2052F AS4002F 12 Series Metricsize 6 2 8 1/4" 5/16" 460 7 8 6 6 10 10,12 JISsymbol Inchsize TubeO.D. 5/16" 1/4" 5/32" 3/8" 1/4" 3/8" 1/2" Flowrate(l/min(ANR)) 230 3.5 20 0.3 290 4.5 130 2 920 14 660 10 390 6 920 14 1390 21 Controlledflow (Freeflow) Effectivearea(mm2) Note)Flowratevaluesaremeasuredat0.5MPaand20C
Information Akihabara UDX 15F, 4-14-1, Sotokanda, Chiyoda-ku, Tokyo 101-0021, JAPAN URL http://www.smcworld.com 2006 SMC Corporation All Rights Reserved 06-E533 Issued: June, 2006 D-DNP P-120 (DN) Stainless Steel Speed Controller (Elbow Type) Series ASG Flow Rate and Effective Area Material: Stainless steel 316 Model ASG22F-M5 Tubing O.D.
CKQ CLKQ Relay, PLC Note 1) D-P4DWZ 5 m 2-wire (14) 2-color display CK1 D-P79WSE 24 VDC 0.3 m Pre-wired connector DC/AC magnetic field Reed auto switch CLK2 Series C(L)KQP D-P74L 3 m 24 VDC 100 VAC 1-color display 2-wire Grommet D-P74Z 5 m Note 1) PLC: Programmable Logic Controller Note 2) There are other applicable auto switches other than the listed above.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.
Through the combination of parallel I/O inputs, 14 points of positioning are available. The speed and acceleration of the positioning can be set by the switch for each operating direction. A single signal sent to a dedicated terminal returns an actuator to the home position.