Plug-in manifold for VQ1*0* valve, Individual lead wire type, P and R ports on one side for space savings, Maximum 8 stations available as standard, 16 port sizes available, Optional DIN rail mount, MFLD, PLUG-IN, VQ1000, VALVE, VV5Q* MANIFOLD VQ 4/5 PORT, UM, VV5Q* BUILT IN FITTING 1.98416 lb
1-C8 exh spacer, VV5Q* MANIFOLD VQ 4/5 PORT*** $27.55 + Add to Quote Add To Cart Add to Cart SMC VVQ2000-R-1-N9 exh spacer, VV5Q* MANIFOLD VQ 4/5 PORT*** $27.55 +
Plug-in manifold for VQ1*0* valve, Individual lead wire type, P and R ports on one side for space savings, Maximum 8 stations available as standard, 16 port sizes available, Optional DIN rail mount, MFLD, PLUG-IN, VQ1000, VALVE, VV5Q* MANIFOLD VQ 4/5 PORT, UM, VV5Q* BUILT IN FITTING .69819 lb
Plug-in manifold for VQ1*0* valve, Individual lead wire type, P and R ports on one side for space savings, Maximum 8 stations available as standard, 16 port sizes available, Optional DIN rail mount, MFLD, PLUG-IN, VQ1000, VALVE, VV5Q* MANIFOLD VQ 4/5 PORT, UM, VV5Q* BUILT IN FITTING 1.67551 lb
Manifold base for VQZ200/300 body ported valves, Top mounted piping, Maximum 20 stations available as standard, 1/8 PT or NPT(VQZ200); 1/4 PT or NPT(VQZ300) P and R ports, Optional DIN rail mount, MANIFOLD, VALVE, VV3QZ* MANIFOLD VQZ 3-PORT, UJ, VV3QZ* BUILT IN FITTING ( 0.99208 lb
Plug-in manifold for VQ1*0* valve, Individual lead wire type, P and R ports on one side for space savings, Maximum 8 stations available as standard, 16 port sizes available, Optional DIN rail mount, MFLD, PLUG-IN W/CHECK VALVES, VALVE, VV5Q* MANIFOLD VQ 4/5 PORT, UM, VV5Q* BUILT IN FITTING 1.59834 lb
Plug-in manifold for VQ1*0* valve, Individual lead wire type, P and R ports on one side for space savings, Maximum 8 stations available as standard, 16 port sizes available, Optional DIN rail mount, MFLD, PLUG-IN W/CHECK VALVES, VALVE, VV5Q* MANIFOLD VQ 4/5 PORT, UM, VV5Q* BUILT IN FITTING 1.90542 lb
OMS0020 How to order L E C C G R ii. Dimensions 40 8. Reference Information 8. 1 Checksum Calculation Procedure The checksum calculation is based on the LRC method. (1) All sent data is added, excluding the Start/End codes. (2) Subtract FFh from the last 2 bytes of the calculation result in step (1). (3) Add 1h to the calculation result in step (2). 8. 2.
How to order L E C C G R ii. Dimensions 71 - 8. Reference Information 8.1 LRC Checksum Calculation Procedure (1) How to calculate the LRC checksum The checksum calculation method in Modbus ASCII mode is based on a Longitudinal Redundancy Checking (LRC) method. (i) All data in the transmitted message is added together, excluding the Start Code : and End Code pair CR, LF.
Construction Seal method: Sealant For R, NPT thread Seal method: Gasket seal For M5, 10-32UNF Meter-out Meter-in Meter-out Seal method: Face seal For G thread Meter-out Component Parts No.
(10 ) 9DIN 101 1 2 2 -8No.PS-OMR0001CN-J 2 B 2 F 0.010.03mm 0.020.15mm 0.050.30mm G H DC24V AC100V AC110V 10 1 10 2 Rc1/8 4 1 C 2 10 N 6 10 3 0 G1/8 F G1/8 3 0.4MPaMPa 1 11 0.4MPaMPa 2 0.2MPaMPa C Rc1/4 3 F 12 G1/4 0.2MPaMPa 4 0.4MPapsi 0.4MPapsi 10 5 N 1 2 3 4 5 6 1 2 NPN1 PNP1 P 10 6 3 4 0.2MPapsi 0.2MPapsi 7 10 4 5 6 M 5 SI 10 8 1 7 L 7 L N S 6 7 8 R
(10 ) 9DIN 101 1 2 2 -8No.PS-OMT0001CN-E 2 B 2 F 0.010.03mm 0.020.15mm 0.050.30mm G H DC24V AC100V AC110V 10 1 10 2 Rc1/8 4 1 C 2 6 10 N 3 10 0.4MPaMPa 0 G1/8 F G1/8 3 1 11 0.4MPaMPa 0.2MPaMPa 0.2MPaMPa 2 3 C Rc1/4 F 12 G1/4 4 0.4MPapsi 0.4MPapsi 5 10 N 1 2 3 4 5 6 1 2 NPN2 PNP2 P 6 10 3 4 0.2MPapsi 0.2MPapsi 10 7 4 5 6 M SI 5 8 10 1 7 L 7 L N S 6 7 8 R
-2No.PS-OMF0005CN-E / 1 1.5 *3) 1 1 [] -3No.PS-OMF0005CN-E () () -4No.PS-OMF0005CN-E () * 5 m -5No.PS-OMF0005CN-E * (RcNPTG) 1/8 79 Nm 1/4 1214 Nm 1.52 2 * () ()() () () -6No.PS-OMF0005CN-E * IP66IP65 () 060 (5 ) * -7No.PS-OMF0005CN-E (ISA2 ) * * (EXH) 5 m 0.2 MPa CE (2 VCA ) () C-R () ()C-R ( ) () AC 10 DC 2 * * 2 0.51.25 mm -10+10 5 -8No.PS-OMF0005CN-E *
Leakage voltage Caution Take note that the leakage voltage will increase when a resistor is used in parallel with a switching element or when a C-R circuit (surge voltage suppressor) is used for protecting a switching device because of the leakage voltage passing through the C-R circuit. The suppressor residual leakage voltage should be as 3% or less of the rated voltage. 3.
( )C-R 3 ( DC 5% AC 15% ) (SSRTRIAC )AC 1) 3 (C-R ) OFF 2)() ZNR 1V 4 VP450-OMU0001 VP4*50, VP4*70, VVP4*0 Series 5 / ( ) (1) ()COMCOM (2) () Sol.1: Sol.2: 1.NPN Sol.1: Sol.2: +() -() 2.NPN 5 VP450-OMU0001 VP4*50, VP4*70, VVP4*0 Series 5 1 ()ISO VG32 2 ()ISO VG32 1 Rc Nm Rc 1/8 35 Rc 1/4 812 Rc 3/8 1520 Rc 1/2 2025 Rc 3/4 2830 Rc 1 3638 Rc 1 1/4 4042 Rc 1 1/2 4850 P
-2No.VQ1000V-OMV0001 / / / / 1 1 1 1 1.5 1.5 1.5 1.5 * * * *3) 3) 3) 3) * * * *3) 3) 3) 3) 1 1 1 1 1 1 1 1 () -3No.VQ1000V-OMV0001 VQ1000/2000 VQ1000/2000 VQ1000/2000 VQ1000/2000 5 5 5 5 / / / / 0.1 2 C-R () C-R DC 3 AC 8% (SSR (SSR (SSR (SSR )AC )AC )AC )AC 1) / / / / () 3 (C-R ) OFF 3 2)() 3) AC ,, SSR SSR 1) 2) ,1V -10 EXH Assy ( ( ( ( ) ) ) ) () 3 () 4 No.VQ1000V-OMV0001
Leakage voltage Take note that the leakage voltage will increase when a resistor is used in parallel with switching element or a C-R circuit (surge voltage suppressor) is used for protecting a switching device because of the passing leakage voltage through the C-R circuit. The suppressor residual leakage voltage should be as follows.
() C-R DC 3% AC 20% (SSR )AC 1) (C-R ) OFF 2)() ( ) () () 3 ( ) () 3 4 VFR6000-OMQ0001 VFR6000 Series 5 / -10 1 1 ( ) Rc Nm Rc 1/8 7~9 Rc 3/4 28~30 Rc 1 36~38 5 VFR6000-OMQ0001 VFR6000 Series 5 / 1) 2)1 ()ISO VG32 (MSDS) 3) 2 ()ISO VG32 \ ( ) 5m 6 VFR6000-OMQ0001 VFR6000 Series 5 / ( ) 3 30 () 1 ( )VG32 2 ()ISO VG32 7 VFR6000-OMQ0001 VFR6000 Series/ / / / DIN DIN DIN DIN DIN
Take note that the leakage voltage will increase when a resistor is used in parallel with a switching element or when a C-R circuit (surge voltage suppressor) is used for protecting a switching device because of the leakage voltage passing through the C-R circuit. The suppressor residual leakage voltage should be as follows. 4.