Guide Cylinder/Compact Type Series MGC ) (Slide bearing type) Deflection Y (mm) Deflection Y (mm) Deflection Y (mm) Deflection Y (mm) St: Stroke (mm) St: Stroke (mm) St: Stroke (mm) Allowable end load F (N) Allowable end load F (N) Allowable end load F (N) MGCM 40-R Stroke (Slide bearing type) St: Stroke (mm) Allowable end load F (N) MGCM 50-R Stroke (Slide bearing type) Deflection Y (mm) St: Stroke (mm) Allowable end load F (
P. 195 DeviceNet P. 199 DI filter P. 195 E Electrical conductivity P. 196 Electromagnetic contactor P. 198 Electromagnetic switch P. 198 EMO circuit P. 198 Ethylene glycol aqueous solution P. 196 eti mark P. 199 ETL mark P. 199 Evaporator P. 192 Expansion valve P. 192 External sensor P. 197 F Facility water P. 193 Flow sensor/Flow switch P. 195 Fluorinated fluids P. 196 Fluorinert P. 196
90 0.5 W W W 0.5 F 117 108 95 76 0.7 C J G5-S 0.1 0 500 1000 1500 81 75 66 51 0.3 CV G 60 55 49 37 0.5 Cylinder stroke (mm) The above curve in the graph refers to P = 0.5 MPa of supply pressure.
R port thread type Series 3 SYA3000 5 SYA5000 Rc Nil G F 40 SYA 7 1 Base mounted N NPT NPTF T P, R port thread type Type of actuation Rc Nil 2 position single G F Port size 1 N NPT Port size Without sub-plate Symbol Applicable series Nil NPTF T 2 position double 1 8 01 SYA3000 Port size With sub-plate 2 1 4 Port size Without sub-plate Symbol Nil With sub-plate 02 SYA5000 1 4 3 position closed
VQC4000 Thread type Note) VVQC4000-3A-1 Series Nil F T Rc G NPT/NPTF Kit type 1 2 4 Thread type VQC1000 VQC2000 VQC4000 Nil F T 1 2 3 Rc G NPT/NPTF S (EX240) kit F, P, T, S (EX250) kit L, M, S (EX500) kit Note) VQC 4000 thread port only Note) Tie-rods (2 pcs.) for additional stations included. U-side end plate assembly !8 U-side end plate assembly part no.
G3/4, Symbol N: NPT3/4) Tank drain port Rc1/4 (Symbol F: G1/4, Symbol N: NPT1/4) Automatic uid ll system (Standard) Pump capacity Supply side pressure range 29 to 73 psi (0.2 to 0.5 MPa) Supply side uid temperature 41 to 95 F (5 to 35C) Automatic uid ll port Rc1/2 (Symbol F: G1/2, Symbol N: NPT1/2) Overow port Rc1 (Symbol F: G1, Symbol N: NPT1) Fluid contact material Stainless steel, Copper
Series PCW PC Wiring System /Series PCW P.593 P.594 P.599 Branch unit: PLC direct connected type Directly mounted on PLC I/O card. Branch unit Connected to PLC I/O card via connection cable. 8 point branch unit Separates two of 8 point I/O transmissions once those are separated from two of 16 point I/O by the branch unit.
R port thread type Series 3 SYA3000 5 SYA5000 Nil Rc G F 40 SYA 7 1 Base mounted N NPT NPTF T P, R port thread type Type of actuation Nil Rc 2 position single G F Port size 1 N NPT Symbol Applicable series Nil Port size Without sub-plate NPTF T 2 position double 1 8 01 SYA3000 Port size With sub-plate 2 Symbol Nil Port size Without sub-plate Without sub-plate (Pilot port: Expect RC) 1 4
AP100 P F P F 887 Series VEF/VEP Flow type: VEF Diagram of Working Principle Flow Characteristics: 3 Port The spool controls the sleeves opening through the balance between the proportional solenoids pulling force (F1) and the springs reaction force (F2).
141 P. 155 P. 172 P. 198 P. 212 P. 183 P. 225 P. 233 P. 251 P. 265 P. 285 P. 294 P. 309 -X 137 Smooth/Low Speed Cylinders CQlY/CQlX Series Added compact foot brackets.
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.)
Connector manufacturers: P Hirose Electric Co., Ltd. P Sumitomo 3M Limited P Fujitsu Limited P Japan Aviation Electronics Industry, Ltd. P J.S.T. Mfg. Co., Ltd. D-sub Connector Cable Assembly Electric Characteristics Cable length (L) Item Characteristics Assembly part no.
Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com E SMC REGULATOR 2 OUT P G Connection thread type MPa IR N F PT NPT PF SUP 2 VEX G Manifold base (3 stations) 1 2 3 AMR IITV20-02-3 ITV2030-311S-X26 P398020-13 ITV2050-212S-X26 1 set (3 station manifold base part no.) 1 set (Electro-pneumatic regulator part no.)
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.)
m AFJ20-02-40-S/AFJ30-03-40-S/AFJ40-04-40-S AFJ20-02-40-T/AFJ30-03-40-T/AFJ40-04-40-T 12 12 AFJ20-02-40-T AFJ30-03-40-T AFJ20-02-40-S AFJ30-03-40-S AFJ40-04-40-S 10 10 Pressure drop [kPa] Pressure drop [kPa] 8 8 AFJ40-04-40-T 6 6 4 4 2 2 Water drop removal type Nominal filtration rating: 40 m Large flow type Nominal filtration rating: 40 m 0 0 0 100 200 300 400 500 600 800 700 900 Flow rate
I s i t p o s s i b l e f o r c a b l e o f I s t h e a n y i n f l u e n c e s t r o k e re a d i n g c y l i n d e r t o o f n o i s e ? b e w i r e d s e p a r a t e l y f r o m t h e p o w e r l i n e ? t h e p o w e r l i n e ?
Data No.1 8 02 0106 sent. 9 01 02 004B 0001 01 02 01 Acquires the INP signal information.
Supply pressure: 0.7 MPa Set pressure: 0.2 MPa Flow rate: 0 /min (ANR) Back pressure: 0.5 MPa Supply pressure: 0.5 MPa IR2000-02 IR2000-02 IR2000-02 0.204 0.5 0.2 Set pressure P2 (MPa) Set pressure (MPa) Set pressure (MPa) 0.4 0.202 F.R.L.
Calculating a Pad's Lifting Force: F r = P u * 1 . 0 3 9 " A 760 1 F " = F r " i theoretical lifting force (kgf), . T F^ Pv A practical lifting force (kgf), stable vacuum pressure (mmHS), A. Selecting the Vacuum Pad l.Calculation Method: A vacuum pad diameter (@D) can be determined by calculation if the lifting force needed to perform the work function is known.
Calculating a Pad's Lifting Force: F r = P u * 1 . 0 3 9 " A 760 1 F " = F r " i theoretical lifting force (kgf), . T F^ Pv A practical lifting force (kgf), stable vacuum pressure (mmHS), A. Selecting the Vacuum Pad l.Calculation Method: A vacuum pad diameter (@D) can be determined by calculation if the lifting force needed to perform the work function is known.