Series CM2-Z 10-/11- ø20, ø25, ø32, ø40 21-/22- Air Cylinder Fittings & Tubing Air Cylinders Rotary Actuators C2 2 x P (Rc, NPT, G) M5 x 0.8 Effective thread length 2 x FL Width across flats B2 2 x NN B (This drawing shows the cases of 20 and 25.)
Recommended Tightening Torque Recommended tightening torque (Nm) Shock absorber fixing thread size Hexagon wrench width across flats (mm) Model 1.5 M3 x 4 0.6 MXW8 1.5 M3 x 4 MXW12 0.6 1.5 M3 x 4 MXW16 0.6 2 M4 x 5 MXW20 0.8 MXW25 2.5 M5 x 6 1 8-7-9 10 Series MXW Dimensions: MXW8 Stroke: 25, 50 mm Operating port 2-M5 x 0.8 J 10 Width across hexagon socket hole 2.5 5.5 Width across flats 8
Recommended Tightening Torque Model Shock absorber fixing thread size Recommended tightening torque (Nm) Hexagon wrench width across flats (mm) MXW8 M3 x 4 0.6 1.5 MXW12 M3 x 4 0.6 1.5 MXW16 M3 x 4 0.6 1.5 MXW20 M4 x 5 0.8 2 MXW25 M5 x 6 1 2.5 154 Series MXW Air Slide Table Construction MXH MXU MXS MXQ MXF MXW MXJ MXP MXY MTS Component Parts No.
Applicable mounting screw: M3 (2 pcs.)
Applicable bore size C1 d H1 C2 d H2 B1 B2 4 SNJ-010B 6 11 12.7 M8 x 1.0 4 3.2 NTJ-006A 6 5.5 6.4 M3 x 0.5 2.4 SNJ-016C SNKJ-016C 10 16 NTJ-010C NTJ-015C 10 16 14 17 16.2 19.6 M10 x 1.0 M12 x 1.0 7 8 8.1 9.2 M4 x 0.7 M5 x 0.8 4 4 The applicable mounting nuts are different from those for standard cylinders. 694 CJ2W-Z Series 10-/1121-/2210, 16 Double Rod Cylinder RoHS How to Order Clean series
Actuating solenoid valve electric signal Valve opening O After a few seconds at 10-6Torr 90% 100% 90% Valve closing Operation time Responce time Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2+...1/Cn) when in series, and C=C1+C2+...Cn, when in parallel. 39 Series XL Technical Data 5 He leakage
Actuating solenoid valve electric signal Valve opening O After a few seconds at 10-6Torr 90% 100% 90% Valve closing Operation time Responce time Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2+...1/Cn) when in series, and C=C1+C2+...Cn, when in parallel. 39 Series XL Technical Data 5 He leakage
Torque Recommended torque in lbf (N m) Hexagonal wrench width across flats Type Fixing thread size 1.5 5.3 (0.6) MXW 8 M3 x 4 1.5 5.3 (0.6) MXW12 M3 x 4 1.5 MXW16 M3 x 4 5.3 (0.6) 2 MXW20 M4 x 5 7.1 (0.8) 2.5 MXW25 M5 x 6 8.9 (1) 139 MXW Series Long Stroke Slide Table Operation Guide Maximum dynamic load and allowable moments are different depending on work mounting orientation,cylinder
Correction Factor C2 for Ambient Air Relative Humidity Vc: Actuator volume (mm3) D : Bore size (mm) s : Stroke (mm) Temperature Relative humidity Correction factor C2 Vc = D2s 4 25C 40C 10C 0.2 0.4 0.6 20% Fig. 2 Piping Volume Chart 0.5 1.0 1.3 40% 140 1.0 1.7 2.8 60% 2.1 4.0 5.9 75% 120 6 tube Correction Factor C3 for Supply Pressure Supply pressure (MPa) Correction factor C3 10 Tube volume
x 10l Metallic painted M3 x 28l Port size: 6 Electroless nickel plated Clear anodized -X Hex. socket head cap screw with spring washer Plate 20Replacement Parts Hex. socket head cap screw with spring washer Solenoid valve Bumper Bumper A Refer to How to order below.
Table 3-1 Amount of radiation and required ventilation Required ventilation amount (m3/min) Heat Differential temp. of 3 C between inside Differential temp. of 6 C between inside radiation Model (kW) and outside of and outside of installation area installation area HRR010-A-10/20Approx.2 40 20 3.2 Installation HRR Series 3-4 HRX-OM-X084 Chapter 3 Transport and Setting Up The water cooled
(Example) For M3: L2 = 6 mm L2 + (3 x P) L2 = Applicable shaft type: W Applicable shaft type: W X = Q2 = M [mm] Size CRB2, CRBU2 Y Q2 15 1.5 to 9 M3 20 1.5 to 10 M3, M4 30 2 to 13 M3, M4, M5 40 4.5 to 15 M3, M4, M5 [mm] Size CRB2 CRBU2 X Q1 X Q1 15 4 to 18 M3 1.5 to 18 M3 20 4.5 to 20 M3, M4 1.5 to 20 M3, M4 30 5 to 22 M3, M4, M5 2 to 22 M3, M4, M5 Symbol: A3 Symbol: A4 The long shaft can
LC6D-507AD-Q (Refer to page 306 for details.) 0.05mm Holding plate: MB1 (1 pc.), Phillips countersunk head screw: M3 x 6l (1 pc.) Phillips binding head screw: M3 x 4l (2 pcs.), Toothed lock washer M3 (2 pcs.) Binding band: T18S (1 pc.)
x 0.45 x 6 (Hexagon socket head cap screw) M3 x 0.5 x 12.5 (Hexagon head bolt) M3 x 0.5 (Hexagon nut) (11) (5 + ST) 2.75 2-M3 x 0.5 through 25 0.2 4 ST 5 + ST 9 + ST 32 + ST 42 + ST Part no.
X M5 M-5ALN-6 Body rotates at 360 around the stud axis M-5J P.2.1-50 M3 female X M3 male M-3UL Barb elbow 3.18/2.18 X M5 soft nylon P.2.1-51 Body rotates at 360 around the stud axis Nipple M-5ALU-3 Fitting to workpiece and fitting fitting connection P.2.1-49 polyurethane 3.18/2 X M5 M3 Universal tee M5 male X M5 male M-5N Body rotates at 360 around the stud axis 4/2.5 X M5 M3 female soft
LC6D-507AD-Q (Refer to page 306 for details.) 0.05mm Holding plate: MB1 (1 pc.), Phillips countersunk head screw: M3 x 6l (1 pc.) Phillips binding head screw: M3 x 4l (2 pcs.), Toothed lock washer M3 (2 pcs.) Binding band: T18S (1 pc.)
Applicable bore size B2 C2 d H2 SNJ-006C 6 8 9.2 M6 x 1.0 4 NTJ-006B 6 5.5 6.4 M3 x 0.5 2.4 DSNJ-010C 10 11 12.7 M8 x 1.0 4 NTJ-010C 10 7 8.1 M4 x 0.7 3.2 SNJ-016C 16 14 16.2 M10 x 1.0 4 NTJ-015C 16 8 9.2 M5 x 0.8 4 -X SNKJ-016C 16 17 19.6 M12 x 1.0 4 Technical Data : For 16 non-rotating type.
Av = Q (8) P Av : Flow coefficient [m2] Q : Flow rate [m3/s] P : Pressure difference [Pa] : Density of fluid [kg/m3] (3) Formula of flow rate It is described by the known unit. Also, the flow characteristics line shown in the Graph (2).
M3 x 0.5 M3 7.5 15 34 3.3 10.5 10 6.5 23 3.4 5.5 3.5 9.5 5 7 26 M3 x 0.5 M3 7.5 15 38 3.3 13 12 6.5 30 3.4 7 3.5 11.5 5 7 33 -X M4 x 0.7 M4 8.5 17 53 4.4 14.5 14 8 35.5 4.5 7.5 4.5 18 4.5 6.5 38.5 M4 x 0.7 M3 14.5 29 62 6.5 3 26 14 34 4 4.5 16.5 6 45 7 20M5 x 0.8 M4 14.5 29 70 8 3 31 17 39 4 5.5 20.5 7 51 8 M6 x 1 M5 17 34 76 9.5 3 41 22 50 4.5 6.5 21 7.5 62.5 10
K V 1 10 XLA S P1P2 XL XL Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2++1/Cn) when in series, and C=C1+C2++Cn, when in parallel.