Membrane Air Dryer .: 10 (NPT threads: 3/8 inch) Hexagon width across flats 17 3/8 1/2 232 91 24 25 Membrane Air Dryer/Unit Type Series IDGM2 IDG75<M2 IDG100<M2 Single Unit Type Model Selection Made to Order Specific Product Precautions Unit Type C (A) Q (B) Port size H Q D M R Purge air for L N dew point indicator K 37 22 P G IN OUT 18 OUT (F) M V
Connector for encoder Screw size: M2 Tightening torque: 0.1 [Nm] lock Connector for electromagnetic brake Screw size: M2 Tightening torque: 0.2 [Nm] Connector for power supply Screw size: M2 Tightening torque: 0.2 [Nm] (3) The servo motor fitting part of each connector is provided with a splash-proof seal (O ring).
CHEMI-CON 13 4 13. 13.2 (1) (2) 13.3 13.4 (LE-S5-LE-S6-LE-S7-LE-S8-)3000[r/min] 13 5 13. 13.5 IP65 (1) 2) 1) 3) 1) 2) 3) 4) 1) 2) 1) 4) 2) (2) M2 0.1Nm : M2 : 0.1Nm M2 0.2Nm : M2 : 0.2Nm M2 0.2Nm : M2 : 0.2Nm (3) (O)(O) (O) 13 6 1 . 2 1.1 . 2 1.2 . 3 2 . 4 3 (WAGO) . 4 4 AC . 5 5 . 6 6 . 7 6.1 . 7 6.1.1 . 7 6.1.2 . 7 6.1.3 . 7 6.2 . 8 7 () . 8 8 EC . 9 8.1 EC
In the case of liquid: $P Q = 1.9 x 106 Av .(9) G Q : Flow rate [L/min] Av : Flow coefficient [m2] $P : Pressure differential [MPa] G : Specific gravity [water = 1] In the case of saturated steam: Q = 8.3 x 106 Av $P (P2 + 0.1) .(10) Q : Flow rate [kg/h] Av : Flow coefficient [m2] $P : Pressure differential [MPa] P1 : Upstream pressure [MPa]: $P = P1 P2 P2 : Downstream pressure [MPa] 31
Y g: Gravitational acceleration, a: Average speed 24 Series MY1W Maximum Allowable Moment/Maximum Load Weight Maximum allowable moment Maximum load weight (kg) m1 Maximum allowable moment (Nm) M1 Bore size (mm) Model M2 M3 m2 m3 Select the moment from within the range of operating limits shown in the graphs.
CY1H15 CY1HT32 CY1HT25 CY1H25 64 56 (Nm) 50 40 30 50 40 30 20 28 26 M1 M2 M3 M2 M3 M1 Model Model 20 CY1H20 CY1H15 16 Moment (Nm) Moment (Nm) CY1H10 CY1H25 1.5 2.5 1.5 28 26 28 13 10 10 CY1H15 CY1HT25 10 16 10 56 85 56 2 2.5 3 4 5 2 3 4 5 CY1H20 CY1HT32 13 16 13 64 96 64 CY1H10 CY1H10 1.5 1 M3 1 0.5 0.5 70 100 300 500 1000 70 100 300 500 1000 Piston speed (mm/s) Piston speed (mm/s) M1 M2
(Nm) ML2B/M1 (Pitch moment) ML2B/M2 (Roll moment) ML2B/M3 (Yaw moment) Pitch moment M1/M1e 10 20 40 Roll moment M2 1.2 2.4 4.8 Yaw moment M3/M3e 3.0 6.0 12 MI W S 40 Model 20 30 YES 20 5 4 3 10 ML2B25 ML2B32 ML2B40 CEP1 If speed or load changes, stopping time may vary and positioning accuracy may be compromised.
Pitch moment Roll moment NO NO M1 = W1 x L1 M2 = W3 x L3 L1 L3 YES The product is operatable at 14.5 mT or less magnetic field ? Is there any influence from magnetic fields ? (Refer to Caution on Handling on pages 706 and 707.) M1 M2 YES W1 NO W3 NO M1 = W4 x L3 M2 = W1 x L2 Do not use it since it will result in a miscount. L3 L2 YES Is water, oil, burr or dust present?
Body A 1 Brass Electroless nickel plated Body B 2 Brass Electroless nickel plated Valve 3 Aluminum O-ring 4 HNBR Spring 5 Stainless steel Pad side Element 6 BC ZP2V-AZP2V-BGasket 7 NBR + Stainless steel 63 Series ZP2V Vacuum Saving Valve Dimensions Vacuum generator side Vacuum generator side M2 M2 H1 H1 Vacuum generator side L2 L1 L3 L2 M2 H1 L2 L33 (L4) (L4) No.0.8 No.0.8 L1 L3 L2 L3
Body A 1 Brass Electroless nickel plated Body B 2 Brass Electroless nickel plated Valve 3 Aluminum O-ring 4 HNBR Spring 5 Stainless steel Pad side Element 6 BC ZP2V-AZP2V-BGasket 7 NBR + Stainless steel 63 Series ZP2V Vacuum Saving Valve Dimensions Vacuum generator side Vacuum generator side M2 M2 H1 H1 Vacuum generator side L2 L1 L3 L2 M2 H1 L2 L33 (L4) (L4) No.0.8 No.0.8 L1 L3 L2 L3
(Moment of inertia) 2 = m2 + m2 L2 D2 8 4.6 x 104 (Calculation example) Cylinder bore size 32 A = 0.07 m, B = 0.02 m, S = 0.012 m, L = 0.045 m, D = 0.02 m m1 = 0.16 kg, m2 = 0.15 kg 1 = 0.16 x + 0.16 x = 1.6 x 104 kgm2 0.012 0.072 + 0.022 2 0.07 2 1.0 x 104 12 120 200 10 100 1000 2 = 0.15 x + 0.15 x 0.0452 = 3.0 x 104 kgm2 0.022 Maximum piston speed [mm/s] 8 Calculation Example (32, clamp
(Fig. 3) Bracket part number for single unit: ZB1-BK1-A Two mounting screws (M2 x 0.55 inch (14 mm), with washer) and two M2 nuts are included. Recommended fittings: KJH04-M5, KJL04-M5, KJW04-M5 Manifold Caution 1.
In the case of liquid: P Q = 1.9 x 106Av (9) G Q : Flow rate [l/min] Av : Flow coefficient [m2] P : Pressure difference [MPa] G : Relative density [water = 1] In the case of saturated aqueous vapor: Q = 8.3 x 106Av P(P2 + 0.1) (10) Q : Flow rate [m3/s] Av : Flow coefficient [m2] P : Pressure difference [Pa] P1 : Relative density [MPa]: P = P1 P2 P2 : Relative density [MPa] Front matter 4
Value is different from Kv and Cv factors for pneumatic purpose due to different test method. 3 3 Saturated steam flow rate Q0 [kg/h] (when Av = 1 x 106 [m2]) Water flow rate Q0 [L/min] (when Av = 1 x 106 [m2]) 2 Upstream pressure P1 = 1 MPa 2 P1 = 0.8 MPa 1 0.9 0.8 0.7 0.6 1 0.9 0.8 0.7 0.6 P1 = 0.6 MPa Example 2 P1 = 0.5 MPa P1 = 0.4 MPa 0.5 0.5 0.4 0.4 P1 = 0.3 MPa Example 1 0.3 0.3 P1
Values of pneumatic Kv are different from Cv because the testing method is different from each other. 3 3 2 2 Upstream pressure Saturated aqueous vapor flow rate Q0 [kg/h] (when Av = 1 x 106 [m2]) P1 = 1 MPa Water flow rate Q0 [l /min] (When < when Av = 1 x 106 [m2]) P1 = 0.8 MPa 1 0.9 0.8 0.7 0.6 1 0.9 0.8 0.7 0.6 P1 = 0.6 MPa Ex. 2 P1 = 0.5 MPa P1 = 0.4 MPa 0.5 0.5 0.4 0.4 P1 = 0.3 MPa
Body A 1 Brass Electroless nickel plated Body B 2 Brass Electroless nickel plated Valve 3 Aluminum O-ring 4 HNBR Spring 5 Stainless steel Pad side Element 6 BC ZP2V-AZP2V-BGasket 7 NBR + Stainless steel 63 Series ZP2V Vacuum Saving Valve Dimensions Vacuum generator side Vacuum generator side M2 M2 H1 H1 Vacuum generator side L2 L1 L3 L2 M2 H1 L2 L33 (L4) (L4) No.0.8 No.0.8 L1 L3 L2 L3
Body A 1 Brass Electroless nickel plated Body B 2 Brass Electroless nickel plated Valve 3 Aluminum O-ring 4 HNBR Spring 5 Stainless steel Pad side Element 6 BC ZP2V-AZP2V-BGasket 7 NBR + Stainless steel 63 Series ZP2V Vacuum Saving Valve Dimensions Vacuum generator side Vacuum generator side M2 M2 H1 H1 Vacuum generator side L2 L1 L3 L2 M2 H1 L2 L33 (L4) (L4) No.0.8 No.0.8 L1 L3 L2 L3
In the case of liquid: P Q = 1.9 x 106Av (9) G Q : Flow rate [l/min] Av : Flow coefficient [m2] P : Pressure difference [MPa] G : Relative density [water = 1] In the case of saturated aqueous vapor: Q = 8.3 x 106Av P(P2 + 0.1) (10) Q : Flow rate [m3/s] Av : Flow coefficient [m2] P : Pressure difference [Pa] P1 : Relative density [MPa]: P = P1 P2 P2 : Relative density [MPa] Front matter
Range Setting Enabled Section Setup M2*10 Option Field Allocation 3 0 to 2 1F1E After restart 1F1F Pn82C Setup M2*10 Option Field Allocation 4 0 to 2 0 After restart 1F1C Pn82D Setup M2*10 Option Field Allocation 5 0 to 2 0 After restart 1D1F Pn82E 10.
In the case of liquid: P Q = 1.9 x 106Av (9) G Q : Flow rate [l/min] Av : Flow coefficient [m2] P : Pressure difference [MPa] G : Relative density [water = 1] In the case of saturated aqueous vapor: Q = 8.3 x 106Av P(P2 + 0.1) (10) Q : Flow rate [m3/s] Av : Flow coefficient [m2] P : Pressure difference [Pa] P1 : Relative density [MPa]: P = P1 P2 P2 : Relative density [MPa] Front matter 4