Table of Contents Model Model L D L D TCU0805-1-N-X6 TCU0425-1-N-X6 1 N x 8 31 3 to 90 L x 5.2 + 200 N x 4 18 1 3 to 90 L x 5.9 + 200 8 5 TCU0805-2-N-X6 TCU0425-2-N-X6 2 42 3 to 40 L x 3 + 200 N x 16 L x 4.4 + 200 N x 8 2 3 to 90 4 2.5 28 TCU1065-1-N-X6 TCU0425-3-N-X6 1 52 3 to 45 L x 5 + 200 N x 10 N x 12 3 3 to 63 L x 2.9 + 200 28 10 6.5 TCU1065-2-N-X6 TCU0604-1-N-X6 2 3 to 35 N x 20 52 L x 3 + 200 N x 6
(For manifold type 20) Body ported 5 L SYJ5 2 M5 1 0 2 5 0 L SYJ5 4 Base mounted Thread type Rc G NPT NPTF Nil F N T Body option Coil specifications Manual override Nil Standard With power saving circuit <24 V, 12 VDC only> 0: Pilot valve individual exhaust for the pilot valve Nil: Non-locking push type T Power saving circuit is not available in the case of D, DO or W type.
Air Grippers PF2W7 20 03 67 M 90 Integrated Display Type Unit specification Flow rate range Series compatible with secondary batteries Nil M With unit switching function Fixed SI unit Note) 0.5 to 4 l/min 2 to 16 l/min 5 to 40 l/min 04 20 40 90 Material restriction Note) Fixed units: Real-time flow rate: l/min Accumulated flow: l Thread type Nil N F Rc NPT G Lead wire M12 3 m lead wire with
10 16 12 4 MXQ-CT12(L)-X11 15 32 G MXQ-CT12(L)-X12 25 42 B C MXQ-CT16(L) 5 23 J MXQ16(L) M10 x 1 M5 x 12 MXQ-CT16(L)-X11 15 33.5 35.5 20 12 17 14 5 33 MXQ-CT16(L)-X12 25 43 A K MXQ-CT20(L) 5 27 MXQ20(L) MXQ-CT20(L)-X11 M5 x 14 M12 x 1.25 15 41 44.5 25 23 37 13 17 6 MXQ-CT20(L)-X12 25 47 MXQ-CT25(L) 5 30 MXQ25(L) M14 x 1.5 M6 x 18 MXQ-CT25(L)-X11 15 40 49 53.5 31 15 28 19 6 MXQ-CT25(L)-X12
Unit AC20C to 40C Dimensions AC20C A Pressure gauge port size G Q F E T L P B C H IN OUT U H L J Pressure gauge (accessory) K M Square embedded type pressure gauge (accessory) Port size N Min. clearance for maintenance Drain Drain D Air filter Mist separator Regulator AC25C, 30C, 40C A Q G F E T Pressure gauge port size L P H B C OUT IN U H L Pressure gauge (accessory) K M Square embedded
I N I n / N l / . \ I n i r N l a / N l ^ l : , ! . : ' : ) ' , + . .
Static torque calculation Tf = F x L (Nm) Load . g = 9.8m/s2 F: Pressing force (N) : Angular acceleration Load .
4, 6, 8 ) 80 + 30 (n 2) (n = 2, 4, 6, 8 ) 35 + 30 (n 2) (n = 2, 3, 4 ) 90 + 30 (n 2) (n = 2, 4, 6, 8 ) 100 + 100 (n 2) (n = 2, 4, 6, 8 ) D-A3 D-G39 D-K39 Different surfaces 100 + 100 (n 2) (n = 2, 3, 4 ) Same surface 1 pc. 75 80 90 10 75 75 80 80 Different surfaces 35 55 90 90 90 + 30 (n 2) (n = 2, 4, 6, 8 ) Same surface 75 + 30 (n 2) (n = 2, 4, 6, 8 ) 80 + 30 (n 2) (n = 2, 4, 6,
(Same surface) 90 95 100 105 110 125 100 D-A3 D-G39 D-K39 60 + 30 (n 2) n = 2, 4, 6, 8 65 + 30 (n 2) n = 2, 4, 6, 8 75 + 30 (n 2) n = 2, 4, 6, 8 80 + 30 (n 2) n = 2, 4, 6, 8 85 + 30 (n 2) n = 2, 4, 6, 8 90 + 30 (n 2) n = 2, 4, 6, 8 35 + 30 (n 2) n = 2, 3, 4 With n pcs.
'i,-.1-)^' l z N F Noz l!
x P U 20 N 5 C (5.1) 10 5.8 4 5.5 36 1 0.2 6.5 6.5 1 3 39 28 10.5 3.3 T-slot A +0.030 0 depth 4 +0.030 0 depth 4 C 4H9 L-M6 Refer to Cross section C-C.
+ 35(n 2) 2 (n = 2, 4, 6)3 35 + 25 (n 2) (n = 2, 3, 4, 5) CM2 Band mounting D-H7/H7W D-H7BA D-H7NF 10 15 60 15 + 45(n 2) 2 (n = 2, 4, 6)3 60 + 22.5 (n 2) (n = 2, 3, 4, 5) CM3 CG1 D-C7 D-C80 10 15 50 15 + 40(n 2) 2 (n = 2, 4, 6)3 50 + 20 (n 2) (n = 2, 3, 4, 5) CG3 D-H7C D-C73C D-C80C 10 15 65 15 + 50(n 2) 2 (n = 2, 4, 6)3 50 + 27.5 (n 2) (n = 2, 3, 4, 5) JMB D-M9V 5 5 10 + 10 (n
Note 6) When N is specified in the end of part number of auto-drain, applicable tubing O.D should be 3/8". 14-2-20 21 F.R.L. Unit Series AC20C to 40C Dimensions AC20C A Pressure gauge port size G Q F E T L P B C H IN OUT U H L J Pressure gauge (Option) F.R.L.
2 105 + 40 n = 4, 8, 12, 16 2 110 + 40 n = 4, 8, 12, 16 n 2 2 (Different sides, Same side), 1 90 95 100 10 D-Y69/Y7PV D-Y7WV 10 + 30 n = 2, 4, 6, 8 (n 2) 2 100 + 30 n = 4, 8, 12, 16 (n 4) (n 4) (n 4) 2 90 + 30 n = 4, 8, 12, 16 2 95 + 30 n = 4, 8, 12, 16 n 2 2 (Different sides, Same side), 1 115 130 20 120 125 n D-Y7BAL 20 + 45 n = 2, 4, 6, 8 (n 2) 2 (n 4) (n 4) (n 4) (n 4) 2 115
Operating Flow Rate 100 90 Suction flow rate of vacuum generator (Q1) Quantity of vacuum saving valves (N) = 80 Minimum operating flow rate (Q2) Vacuum pressure (kPa) 70 Example) Vacuum saving valve used: ZP2V-A8-05 From Table 1, Q2 can be calculated as 5.0 L/min (ANR). 60 Q2 = 5.0 L/min (ANR) 50 N = 6 (unit) 31 {L/min (ANR)} 5 {L/min (ANR)} 40 30 N = 6 (unit) Table 1.
Operating Flow Rate 100 90 Suction flow rate of vacuum generator (Q1) Quantity of vacuum saving valves (N) = 80 Minimum operating flow rate (Q2) Vacuum pressure (kPa) 70 Example) Vacuum saving valve used: ZP2V-A8-05 From Table 1, Q2 can be calculated as 5.0 L/min (ANR). 60 Q2 = 5.0 L/min (ANR) 50 N = 6 (unit) 31 {L/min (ANR)} 5 {L/min (ANR)} 40 30 N = 6 (unit) Table 1.
Operating Flow Rate 100 90 Suction flow rate of vacuum generator (Q1) Quantity of vacuum saving valves (N) = 80 Minimum operating flow rate (Q2) Vacuum pressure (kPa) 70 Example) Vacuum saving valve used: ZP2V-A8-05 From Table 1, Q2 can be calculated as 5.0 L/min (ANR). 60 Q2 = 5.0 L/min (ANR) 50 N = 6 (unit) 31 {L/min (ANR)} 5 {L/min (ANR)} 40 30 N = 6 (unit) Table 1.
Operating Flow Rate 100 90 Suction flow rate of vacuum generator (Q1) Quantity of vacuum saving valves (N) = 80 Minimum operating flow rate (Q2) Vacuum pressure (kPa) 70 Example) Vacuum saving valve used: ZP2V-A8-05 From Table 1, Q2 can be calculated as 5.0 L/min (ANR). 60 Q2 = 5.0 L/min (ANR) 50 N = 6 (unit) 31 {L/min (ANR)} 5 {L/min (ANR)} 40 30 N = 6 (unit) Table 1.
. output 8 PT7 RY(n 2)9 Reserved RX(n 2)A RY(n 2)A Position/speed specifying system selection to Reserved RX(n 2)F selection RX(n 3)0 RY(n 2)B Absolute value/incremental value to Reserved RY(n 2)C RX(n 3)9 to Reserved RX(n 3)A Trouble ALM 15 RY(n 2)F RX(n 3)B Remote station communication ready CRD RY(n 3)0 to Reserved RX(n 3)C RY(n 3)9 to Reserved RY(n 3)A Reset RES RX(n 3)F RY(n 3)B to Reserved