LFE-OMY0008 No.LFE*-OMY0008 / / / / / / / / LFE# SMC SMC SMC SMC 2 11 13 14 16 18 19 21 24 26 26 F1 OUT1 28 F2 OUT2 36 F3 40 F10 41 F20 45 F22 46 F30 47 F32 48 F33 50 F34 51 F80 52 F81 53 F82 54 F90 55 F98 56 F99 57 58 60 61 64 66 67 70 71 1 No.LFE*-OMY0008 (ISO/IEC) (JIS) 1 2 1) ISO 4414:Pneumatic fluid power -General rules relating to systems.
4.6 9.5 14 56 38 2.5 depth 8.5 2.6 Approx. 70g LFE38 62 53 4.6 3.5 20 68 43 2.5 depth 8.5 2.6 Approx. 70g -71No.LV50***-OMQ0002-G Dimension of the cable with M12 connector lead wire (LFE-1-A3) 4 Black Blue 3 White 2 1 Brown -72No.LV50***-OMQ0002-G Revision A : Contents revised in several places.
Save the displayed waveform screen (print screen). -53- 6.10 Display All Monitor List The method how to obtain the electric actuator condition is described with the display all function of the setup software. Click Monitor Display All of the setup software to display Display All window. The condition of each item is displayed.
When monitor command "Read alarm history" is sent to the controller with controller ID: 1 Transmission data to be used in the checksum calculation "0", "1", "0", "3", "0", "6", "0", "0", "0", "0", "0", "4" (i) 01h + 03h + 06h + 00h + 00h + 04h = 0Eh (ii) FFh 0Eh = F1h (iii) F1h + 01h = F2h Checksum = "F2" (= 46h, 32h) 8.2 CRC Check Sum Calculation Procedure (1) How to calculate the CRC
MY1 HT m2 m3 MY1 W MY1 W Moment (Nm) M3=F3 x L3 F3 F2 M1=F1 x L1 F1 M2=F2 x L2 MY2C L2 L1 L3 Maximum Load Mass MY2 H/HT Select the load from within the range of limits shown in the graphs. Note that the maximum allowable moment value may sometimes be exceeded even within the operating limits shown in the graphs. Therefore, also check the allowable moment for the selected conditions.
F2 P3 wSub-plate Thread type Port size Thread type Rc G Note) Symbol Port size 1/4 3/8 Nil F N T Symbol 1 2 NPT NPTF !1Gasket DXT172-7 !
No.PF-OMS0001CN-A // PFMC7501 PFMC7102 PFMC7202 2 10 11 12 14 15 17 18 [] 22 OU1OUT2 {3 ] 23 [] 25 26 F0 27 F1 OUT1 29 F2 OUT2 37 F3 42 F10 43 F20 47 F22 48 F30 49 F31 50 F80 OFF 51 F81 52 F82 53 F90 54 F98 56 F99 57 58 62 63 65 66 66 69 71 -1No.PF-OMS0001CN-A (ISO/IEC)(JIS) *1) *2) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO
No.PF-OMM0004-D / / PF3W7## SMC 2 11 13 14 16 17 19 21 24 26 26 F1 OUT1 60 F2 OUT2 36 F3 42 F10 43 F20 47 F22 48 F30 50 F80 51 F81 52 F82 53 F90 54 F98 55 F99 56 57 61 61 65 65 71 79 81 88 -1No.PF-OMM0004-D (ISO/IEC) (JIS) 1 2 1) ISO 4414:Pneumatic fluid power -General rules relating to systems.
OUTPUT 35 9-3-5. 36 10 3744 11 11-1. 11-1-1. 45 11-1-2. 4548 11-1-3. 48 11-2. 11-2-1. 4952 11-2-2. 53 11-3. 11-3-1. 53 12 12-1. 54 12-2. 54 13 13-1. 5557 13-2. () 5758 14 14-1. 5960 - 1 1 1 1 (ISO/IEC)(JIS) 1) 2) *1) ISO 4414:Pneumatic fluid powerGeneral rules relating to systems ISO 10218-1:2006Robots for industrial environments-Safety requirements-part1
SERIES NVEP PRESSURE TYPE FLOW CHARACTERISNCS Flqv Rateg NvERtl2O-1-02 ftimary Pressure P1 : 150 PSIG {9.9 Kg/crn2} iYo CurrnyPressure NVEP3120/3140 OPERATING PRINCIPLES The secondary pressure is controlled by the movement of the spool which is balanced belween the Solenoid Force (F1) and F2. F2 results lrom the secondary pressure (P2) acting on the end face of the spool.
When A port pressure is lower than P1 port pressure, F1 becomes larger than F2, and the pressure regulating piston moves downwards,opening the lower poppet valves.Thus air is supplied from P port to A port.(DRW(3)) When A port pressure rises enough to restore the balance, the regulator valve returns again to the DRW(2) condition.
SERIES NVEP PRESSURE TYPE FLOW CHARACTERISNCS Flqv Rateg NvERtl2O-1-02 ftimary Pressure P1 : 150 PSIG {9.9 Kg/crn2} iYo CurrnyPressure NVEP3120/3140 OPERATING PRINCIPLES The secondary pressure is controlled by the movement of the spool which is balanced belween the Solenoid Force (F1) and F2. F2 results lrom the secondary pressure (P2) acting on the end face of the spool.
l6, ~5'K5 BA..Q4 BA-05 BA-06 D-A:3, DA4 D.G3K3 B01-04M B001..Q5M B01-06M B79-0-879 A41--0-A41 880-0880 A49--0-A49 851 0-851 Note)These auto SWitch as cannot be used m magnetic fields.
Stroke adjustment unit mounting diagram Stroke adjustment unit Stroke Adjustment Unit Symbol Right side stroke adjustment unit Intermediate fixing spacer Example of L6L7 attachment Left side Right side L: With low load shock absorber + Adjustment bolt L unit Short spacer L unit Long spacer Without unit With short spacer With long spacer SL L L6L L7L SL6 LL6 L6 L7L6 SL7 LL7 L6L7 L7 Without
Screw Type: Rc, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: None, Lead Wire Length(m): -, Lead Wire Connector: -, The number of the switches: -, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None
Screw Type: Rc, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: None, Lead Wire Length(m): -, Lead Wire Connector: -, The number of the switches: -, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None
Screw Type: Rc, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: None, Lead Wire Length(m): -, Lead Wire Connector: -, The number of the switches: -, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None
Screw Type: Rc, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: None, Lead Wire Length(m): -, Lead Wire Connector: -, The number of the switches: -, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None
Screw Type: Rc, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: M9NW, Lead Wire Length(m): 0.5, Lead Wire Connector: M12 4‑pin A cord (normal key) plug connector, The number of the switches: 3, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None
Screw Type: NPT, Cushion: Air cushion, Specification: Magnet built-in, Auto Switches: None, Lead Wire Length(m): -, Lead Wire Connector: -, The number of the switches: -, Custom-made Specifications: 0.1 to 0.8, End Block: L6, Custom-made: None