4-channel Flow Monitor ( compatible) The recommended bend radius of the lead wire is 6 times the outside diameter of the sheath, or 33 times the outside diameter of the insulation material, whichever is larger. Replace the damaged lead wire with a new one. Wire correctly. Incorrect wiring can break the product. Do not perform wiring while the power is on.
-2No.PF-OMN0009CN-F / 1 1.5 3 3)1 1 () [] -3No.PF-OMN0009CN-F () () () () -4No.PF-OMN0009CN-F () * UL UL1310 2 UL1585 2 30[Vrms] 42.4[V ]2 UL (), (0~90 )3mPas(3cP)(0~90 ) () <> -5No.PF-OMN0009CN-F * 16 FG (49 N () M8 IN IN OUT OUT OUT OUT IN 40 -6No.PF-OMN0009CN-F * () 6 33 () () 10 m DC(-)() -7No.PF-OMN0009CN-F * ( ) () CE -8No.PF-OMN0009CN-F * 3 * -9No.PF-OMN0009CN-F
Operation at occurrence of circulating fluid discharge pressure rise alarm RUN HIPRS ALARM(Alternately displayed) HRR Series 5.5 Advanced setting mode 5-33 HRX-OM-X084 Chapter 5 Display and Setting of Various Functions The user can decide the chiller behaviour if alarm "AL 09: circulating fluid discharge pressure rise" occurs.
Operation at occurrence of circulating fluid discharge pressure rise alarm RUN HIPRS ALARM(Alternately displayed) HRR Series 5.5 Advanced setting mode 5-33 HRX-OM-W002 Chapter 5 Display and Setting of Various Functions The user can decide the chiller behaviour if alarm "AL 09: circulating fluid discharge pressure rise" occurs.
RUN Alarm setting menu TOP screen HRR Series 5.5 Advanced setting mode 5-33 HRX-OM-X071 Chapter 5 Display and Setting of Various Functions Changing of circulating fluid discharge pressure rise alarm behaviour 2. Press the [] key. Displays screen for changing the chiller behaviour when the circulating fluid discharge pressure rise alarm occurs.
XL-OMY0001 L // XLA-2 2 11 4 , 2.2 5 , , , , 33 7 4. 9 5 11 6. 13 7 14 1 XL-OMY0001 *1) *2) (ISO/IEC) (JIS) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO 4413: Hydraulic fluid power -General rules relating to systems IEC 60204-1: Safety of machinery -Electrical equipment of machines (Part 1: General requirements) ISO 10218: Manipulating
25.4 25.4 25.4 25.4 28.7 27.7 27.7 27.7 40.7 40.7 42.7 65.4 65.7 A 10 20 30 40 50 75 100 125 150 10 20 30 40 50 75 100 125 150 MXQ6B 18 7.4 7.4 7.4 7.4 7.4 1 11.6 11.6 17.6 34.6 11.6 MXQ8B 29 13.9 13.9 13.9 13.9 13.9 13.9 2 9.1 9.1 17.1 17.1 36.1 36.1 MXQ12B 16.5 16.5 16.5 16.5 16.5 16.5 16.5 16.5 24.1 18.1 18.1 25.1 25.1 31.1 50.1 50.1 MXQ16B 20.6 20.6 20.6 20.6 20.6 20.6 20.6 20.6 20.6 33
. # 0 0 O R [CR] No. 0 0: 1: # 0 0 O W [CR] No. 0 0: 1: # 0 0 O W [CR] No. 33 - # 0 0 I R [CR] No. # 0 0 I R [CR] No. 0 0:A /B 1:UP/DOWN # 0 0 I W [CR] No. 0 0:A /B 1:UP/DOWN # 0 0 I W [CR] No. 34 - # 0 0 B R [CR] No. # 0 0 B R [CR] No. 0 0:OFF 1:ON # 0 0 B W [CR] No. 0 0:OFF 1:ON # 0 0 B W [CR] No. 35 - # 0 0 R S [CR] No. # 0 0 R S [CR] No. # 0 0 H R [CR] No. # 0 0 H R
The Directi on of Memory 33 9-3-2 Input Signal Content Start One started, setting position will be inputted. One step of movement per one shot (above 50msec). Next : Start signal (above 50msecs signal) will be received and activated to carry out subsequence step, only if homing has been performed and origin signal has been fed back to controller.
No.CE*-OMQ0011-A : : ML2B CEU2 SMC 1 4 2 2-1. 10 2-2. 11 2-3. 11 2-4. 11 3 3-1. 1213 3-2. 14 3-3. 1516 4 4-1. 17 4-2. 1819 4-3. 2021 5 5-1. () 22 5-2. 22 5-3. 23 6 6-1. () 24 6-2 24 6-3 25 7 7-1 26 7-2 27 7-3 28 8 8-1 29 8-2 29 - 9 9-1 9-1-1. 3031 9-1-2. 32 9-2. 9-2-1. 32 9-2-2. 32 9-3. 9-3-1. 33 9-3-2. 34 9-3-3.
Allowable load a b Allowable thrust loadN Allowable momentNm Size Allowable radial load a b Basic type High precision N type 1 31 41 41 0.56 0.84 2 32 45 45 0.82 1.2 3 33 48 48 1.1 1.6 7 54 71 71 1.5 2.2 Unit used as flange mount Rotary table can be mounted from three directions-Two side of axial direction and one side of lateral face.
Note 5) Leave an interval of 15ms (the recommendation is 30ms) or more between input signals and maintain the state of the signal for 15ms (the recommendation is 30ms) or more, because PLC processing delays and controller scanning delays can occur. 29 - 2) Signals when Stopped: In the event when EMG is used / See 5.1 Warning (9) on p. 33 The operating sequence is 1. Stop 2.
LEF-OM00601 / / / LEF Series LECSeries /LEC6 . 2 1/. 4 . 4 . 5 . 7 2 . 9 LEF / . 9 LEF/ . 12 . 14 . 15 3 . 17 . 17 . 18 . 21 . 27 4 . 30 5 . 31 51 . 31 52 . 32 53 . 32 54 . 33 55 . 34 56 . 34 6. 35 61 . 35 62 . 35 63 . 36 64 . 36 65 . 38 . 39 LEF Series/ (ISO/IEC) (JIS)1)2) *1) ISO 4414:Pneumatic fluid power -General rules relating to systems.
/LEHS .20 4.1 . 20 4.2 . 21 4.3 . 22 5.23 5.1 . 23 5.2 . 24 5.3 . 27 . 27 . 29 (1). 31 (2). 32 (3). 33 . 34 5.4 . 36 . 36 . 38 1 - 6.39 7.40 7.1 . 40 7.2 . 41 7.3 . 41 7.4 . 42 7.5 . 44 7.6 . 44 8.45 8.1 . 45 8.2 . 46 8.3 . 50 8.4 . 53 .54 2 - LEH Series / (ISO/IEC)(JIS)1) 2) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO 4413: Hydraulic fluid power -General
CN5I/O . 23 6.1 . 23 6.2 (NPNPNP ) . 23 (1) I/O (NPNPNP ) . 23 (2) I/O . 23 6.3 . 24 6.4 I/O . 27 7. . 28 7.1 . 28 7.2 . 31 7.3 . 33 8. . 34 8.1 . 34 8.2 . 34 8.3 . 35 (1) . 35 (2) (). 35 (3) . 35 8.4 . 36 8.5 . 36 9. (). 37 9.1 . 37 9.2 . 38 10. . 39 10.1 . 39 10.2 I/O . 39 (1) . 39 (2) . 40 (3) . 41 (4) HOLD. 42 (5) . 42 2 - 6 . 42 (7) . 43 11. . 44 11.1 . 44 11.2 (). 45 11.3 I/O . 46 11.4
CN5I/O .23 6.1 /.23 6.2 /(NPNPNP ).23 (1) I/O (NPNPNP ).23 (2) I/O .23 63 /.24 64 I/O .27 7 .28 71 .28 72 .31 73 .33 8 .34 81 .34 82 .34 83 .35 1 .35 2 (.35 3 .35 84 .36 85 .36 9 .37 91 .37 92 .38 10 .39 101 .39 102 I/O .39 1 .39 2 .40 3 .41 4 HOLD.42 5 .42 2 - 6 .42 7 .43 11 .44 111 [5m ].44 112 [820m].44 113 [5m ].45 114 [820m] .45 115 I/O .46 116 .46 117 .47 12. .48 12.1 .48 12.2 .49 13
LEC . 8 (4)GW . 8 (5)GW . 8 (6) . 9 (7) . 9 3 . 10 3.1 . 10 3.2 . 12 3.3 . 13 (1)(LECGEN1) . 13 (2)DIN (LECGEN1D) . 13 3.4 . 14 (1) . 14 (2) . 14 4. . 15 4.1GW (B RATE) . 15 4.2 (CN2SW) . 16 4.3LEC . 16 4.4GW EtherNet/IP . 22 5. . 26 5.1 CN4 . 26 5.2 CN3 . 26 5.3 CN1CONT . 26 5.4 CN2PC/TB . 27 6.CN4 . 28 1 - 6.1 . 28 6.2 . 29 6.3 . 30 . 30 7.CN1(CONT) . 31 7.1 . 31 7.2 . 33
37.5 PA Rc 1/8 Rc 1/8 Rc 1/4 Applicable cylinder ML2B25 ML2B32 ML2B40 Applicable cylinder ML2B25 ML2B32 ML2B40 Stroke Adjustment Unit With shock absorber: ML2B Bore size Stroke L TT h EB FF EA Stroke adjustment unit ED FA TA (Absorber stroke) FB FC Shock absorber Cushion needle EC FH EY h 3.5 4.5 4.5 EA 10 12 15 EB 20 25 31 EC 6.5 8.5 9.5 ED 60 74 94 EY 53.5 67 81.5 FA 46.7 67.3 67.3 FB 33
46 50 27.3 47 15 3H9 3.5 M5 x 0.8 8 32 27 3H9 3.5 19 3H9 3.5 M10 x 1.5 15 M6 x 1 M5 x 0.5 M12 x 1.25 37 168.5 58.5 63.5 39 54 20.5 4H9 4.5 M6 x 1 10 43 36 4H9 4.5 24 4H9 4.5 M10 x 1.5 15 M6 x 1 M5 x 0.5 M12 x 1.25 40 184 63.5 69 36.4 57 23 4H9 4.5 M6 x 1 10 48 39 4H9 4.5 28 4H9 4.5 M12 x 1.75 18 M8 x 1.25 M6 x 0.75 M14 x 1.5 46 214.5 76 78 42.4 66 26.5 5H9 5.5 M8 x 1.25 12 55 45 5H9 5.5 33
) 68 14 39 14.5 16.5 49 30.4 34.7 4.7 4.9 7 8.1 25 30 11 14 14 M8 x 1.25 M10 x 1.5 M10 x 1.5 78 (13) 76 16 47 18.5 55 40.4 Size Rotation K Q S W Key dimensions TF (H9) TG (H9) TL JJ US TA TD G L UW TB TC M N b l 90 180 90 180 90 180 3 29 104 130 122 153 20 0 0.03 1 15 59 24.5 8 11 9.6 11.5 4 13.5 27 4 4 2.5 74 20 M5 x 0.8 depth 6 0 0.03 30 2 18 65 27 10 13 11.4 13.5 19 36 4 4 2.5 83 4 33