NCA1 3/4-16 1.13 5.80 1.500 1.81 1/2-20 2.88 4.10 2.75 1.38 5.88 600 (6") 1.375 1-14 1.63 6.90 2.000 1.81 1/2-20 3.13 4.88 3.25 1.63 6.63 800 (8") 1.375 1-14 1.63 9.10 2.000 2.31 5/8-18 EE 1/2 NPT 3/4 NPT 3/4 NPT E 5.50 6.50 8.50 LF+ 4.50 5.00 5.13 3.25 6.44 4.25 1.63 6.75 7 Series NCA1 Cylinder Large Bore Dimension Drawings MF1 Rod side rectangular flange (F) P + Stroke W 2-EE B 4-FB KK MM R
(P980) . 20-19 20.4.4 Identification & Maintenance (I&M) . 20-20 20.4.5 Reset To Factory . 20-21 20.5 STATE TRANSITION . 20-22 20.5.1 Basic State Machine . 20-22 20.5.2 FSA state . 20-25 20.5.3 Controlword/Statusword . 20-27 20.5.3.1 Controlword . 20-27 20.5.3.2 Statusword . 20-30 20.6 CONTROL MODE . 20-36 20.6.1 Selection of control mode . 20-36 20.6.2 Control switching . 20-37 20.6.3 Profile
Driver Driver Servo amplifier Servo motor Servo amplifier Servo motor U U U U CAUTION V V M V M V W W W W Connecting a servo motor of the wrong axis to U, V, W, or CN2 of the driver may cause a malfunction. 3 3 3.
(1) 0+55() 0+40() -20+65() -15+70() 90%RH() 80%RH() 90%RH() () 1000m LECSS2-T5 LECSS2-T7 LECSS2-T8 LECSS2-T9 () 5.9m/s2 XY49m/s2 (2) (FR-BIF) (UVW), A 5 (UVW)(UVW) U U U U V V M V M V W W W W DC DC 24 V DC 24 V DOCOM DOCOM RA RA U,V,WCN2 (3) (4) A 6 () (5) DC24V ALM()MBR( ) RA B U DC 24 V (6) 10 (7) A 7 () 1.(:) (1) (2) 2.(:) (1) 1 (2) (3) (4) , [](:) EEP-ROM
10, 15, 20, 25, 30, 40 5, 10, 15, 20, 25, 30, 40 5, 10, 15, 20, 25, 30, 40 5, 10, 15, 20, 25, 30, 40 1/4" 6 12 3/8" 10 20 5/8" 15 40 3/4" 20 60 1" 25 80 32 1-1/4" 80 1-1/2" 40 80 2" 50 80 2-1/2" 63 80 Note) The longer the stroke, the larger the amount of deflection in a cylinder tube.
Switch Model NCDJP Relay/PLC, Sequencer, IC Circuit Applications <24V 24VDC <24V 100VAC 24VDC 100VAC Voltage Rating L E A D W I R E L E N G T H A U T O S W I T C H 50MA 5~40MA 50MA 20MA 5~40/ 5~20MA Maximum Current 0.5m L 3m Standard D With Auto Switch 0 2.4V 0 2.4V Internal Voltage Drop 0 Leakage Current M O U N T T Y P E 1.2Ms Switching Time No Yes No Yes Indicator Light B Nose Mount *
Cooling Method: A (Air-cooled Refrigeration), Pipe Thread: N [NPT (w/Rc-NPT Conversion Fitting)], Power Supply: 20 [3-phase 200 VAC (50 Hz); 3-phase 200 to 230 VAC (50/60 Hz], Option: JM (J + M)
Cooling Method: W (Water-cooled Refrigeration), Pipe Thread: N [NPT (w/Rc-NPT Conversion Fitting)], Power Supply: 20 [3-phase 200 VAC (50 Hz); 3-phase 200 to 230 VAC (50/60 Hz], Option: JM (J + M)
Cooling Method: Air-cooled Refrigeration, Pipe Thread: N [NPT (w/Rc-NPT Conversion Fitting)], Power Supply: 20 [3-phase 200 VAC (50 Hz); 3-phase 200 to 230 VAC (50/60 Hz], Option: J + M
Cooling Method: Water-cooled Refrigeration, Pipe Thread: N [NPT (w/Rc-NPT Conversion Fitting)], Power Supply: 20 [3-phase 200 VAC (50 Hz); 3-phase 200 to 230 VAC (50/60 Hz], Option: J + M
[C] 5 10 15 20 25 30 35 Circulating fluid temperature [C] HRS090-W-20/40 (50 Hz) HRS090-W-20/40 (60 Hz) 14 12 12 10 Facility water temperature 32C Facility water temperature 32C Cooling capacity [kW] Cooling capacity [kW] 10 8 8 6 Facility water temperature 40C Facility water temperature 40C 6 4 4 2 2 0 0 5 10 15 20 25 30 35 Circulating fluid temperature [C] 5 10 15 20 25 30 35 Circulating
. 5-18 5.8.4 Command:LOC Key-lock setting (R) . 5-19 5.8.5 Command:LOC Key-lock setting (W) . 5-20 5.8.6 Command:STR Saves data (W) . 5-21 5.9 Negative response . 5-22 Chapter 6 Communication alarm function . 6-1 6.1 Communication alarm occurs . 6-1 6.2 Communication alarm reset . 6-2 6.3 Setting and checking . 6-2 6.3.1 Setting and checking items . 6-2 HRS090 Series HRX-OM-T004 Contents
Power consumption P: 20 [kW] Q = P = 20 [kW] Cooling capacity = Considering a safety factor of 20%, 20 [kW] x 1.2 = V: Power supply voltage P 24 [kW] Power consumption e Derive the heat generation amount from the output. Output (shaft power, etc.) W: 13 [kW] w Derive the heat generation amount from the power supply output.