Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: M [Applicable to DI Water (Deionized Water) Piping]
Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: T (High-lift Pump)
Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: BM (B + M)
Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: B (Earth Leakage Breaker)
Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: J (Automatic Water Supply Function)
Cooling Capacity: 018 (Cooling Capacity: 1700/1900W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: BJ (B + J)
HRX-OM-W038 0.0 5 0 10 20 30 5 0 10 20 30 Circulating fluid flow[L/min] Circulating fluid flow[L/min] Fig. 9-7 Pump capacity(HRS040--20-(BJM)) 9.6.2 HRS040--20-T,-MT 0.5 50 Available area 0.4 40 Circulating fluid pressure[MPa] Pump head[m] Outlet50Hz Outlet:60Hz 0.3 30 0.2 20 0.1 10 Return port Available area 0 0.0 0 10 20 30 40 Circulating fluid flow[L/min] Fig. 9-8 Pump capacity(HRS040--20-T/-MT)
A large digital display provides a clear view of the current and set values.
flat 10 Width across flat 10 A A 10 10 2 2 1.8 1.8 8.4 6 Dimensions (per stroke) Dimensions (per stroke) 10 13 Weight (g) Non-rotating (J) Rotating (K) Weight (g) Non-rotating (J) Rotating (K) 14 11 A B D A B D Model Model ZP3-T13B;3-B5 ZP3-T13B;6-B5 ZP3-T13B;10-B5 ZP3-T10B;3-B5 ZP3-T10B;6-B5 ZP3-T10B;10-B5 8.5 9.7 11.7 8.6 9.8 11.8 8.6 9.7 11.7 8.7 9.8 11.8 15 18 22 34.5 41 51 11 14.5 20.5
E MGPL (ball bushing)/Dimensions A, E (mm) (mm) E E A 10 to 39st 43 49 A Bore size (mm) Bore size (mm) 10 to 74st 42 46 75 to 100st 60.5 64.5 101 to 250st 85 95 10 to 74st 0 0 75 to 100st 18.5 18.5 101 to 250st 43 49 40 to 100st 55 65 101 to 250st 85 95 10 to 39st 1 3 40 to 100st 13 19 101 to 250st 43 49 12 16 12 16 A E A E Bore size (mm) Bore size (mm) 20 to 74st 53 53.5 75 to 200st 84.5
Cooling Capacity: Cooling Capacity: 1100/1300W, 50/60 Hz, Cooling Method: Air-cooled Refrigeration, Thread: Rc, Option: M + T
Cooling Capacity: 012 (Cooling Capacity: 1100/1300W, 50/60 Hz), Cooling Method: A (Air-cooled Refrigeration), Thread: Rc, Option: MT (M + T)
[Horizontal and lateral mounting] A B SOL.3 W RE A B A magnetic field of 14.5 mT is equivalent to a position that has about 18 cm radius from a welded part using about 15,000 amperes of welding amperage. When using it in a stronger magnetic field, cover the sensor with magnetic and shield it.
12 15 h 3.5 4.5 4.5 Applicable cylinder ML2B25 ML2B32 ML2B40 10-13-15 13 Series ML2B Dimensions Side support A MY-SA 2-G F E 2-H C D A B Side support B MY-SB 2-J C D A B (mm) A 61 70 87 B 75 84 105 C D E F G H J Part no.
A-9 Comparison of a situation sketch with the simulation set-up and the ckcuil diagram P E U x A ' I c T E c H N o L o G Y S A M P L E D I A G B A M S We will look at this in a sample diagram. Diagram A-10 is the circuit tor the sequenc: "A+, B+, B-, A-". ll is divided into the thre levels, the power section on top, the signal inputrs on the bottom and in between the 'signal procssing'.
From Table 3.7: At 1soo, 10 m3 of air can hold a maximum of 13.04g/m..10m" = 130.4 g P N E U A T I c T E c H t t o L o G Y At 650/o r.h. the air will conlain 130.4 g '0.65 = 84.9 g {a) The reduced volume ol compressed air at 6 bar pressur can be calculated: pl'v1 = pzvz = p; v1 = v2 = +H# '10 m3 = 1.44 mc From Table 3.7 1.44m3of air at 25oC can hold a maximum of 23'76 g '1 '44 = 34.2 g (
CEP1 CE1 A magnetic field of 14.5 mT is equivalent to a position that has about 18 cm radius from a welded part using about 15,000 amperes of welding amperage. When using it in a stronger magnetic field, cover the sensor with magnetic and shield it.
(I$odell A A I D E t H WT $tl oEfio.l il{s} 57.0 6i.0 l(10 x 1.0 3.0 N/A 8.6 49.4 8.6 10.? N/A r{/A N/A 0 t.t5rir(B) 8 t . 8 91.1 Ml2 x 1.0 3.3 l.l/A 8,6 71.4 0.9 14.2 N/A .0 9.7 (r.R)0Efl.251rr(r)8r.8 9 1 . ? M l { x 1 . 5 J.J /A 1.2 71.4 0.9 t4.2 N/A r2.0 12.1 (r.R)0Efti.35rJr(Bl 100,6 0.7 l l 6 x 1 . 5 4.0 N/A ).2 87.4 1.2 t4.5 0.5 t4.0 12.7 l0 [.5t](B] 9E_6 I t 0,5 [!
A large digital display provides a clear view of the current and set values.
AC DC 2. 10 3 10 (2) ()40 10(555) (10.1) A P (10.1) KT [m2] [W] [] [56] A P T K (10.1),P 10.1A 10.1 40() () () 10.2 10 4 10 10.3 (E6) OFF 10 11000 (EM1) (EM1) 10.3.1 (1) 10.3 (10.2) ((2)(a)(b)) ON EM1 (EM1) OFF V0 te 10.3 t 1J Lmax V L 0 (10.2) e 60 J M Lmax VO JM JL te [mm] [mm/min] [kgcm 2] [kgcm 2] [s] [s] 7kW10ms11k22kW (50ms) 10 5 10 (2) (10.2) (a) 200V 25 73 20 23