%silltr 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 [!
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
Endurance 10 G; X, Y, Z directions, 3 times each Impact resistance 350 g or less Weight 1) 90 phase difference input Multi-counter/Dimensions A phase I 24-M3 x 0.5 B phase J A B C D A COM COM COM B 12 VDC GND F.G.
Bore size (mm) B A B A B A 12 11 78 12 79 8 75 20 15 85 16 86 12 82 Operating Range Auto switch model Bore size (mm) 12 20 10 3 D-A9/A9V 6 D-M9/M9V D-F9W/F9WV D-F9BAL 2.5 3 5 Since this is a guideline including hysteresis, not meant to be guaranteed.
LEFT RIGHT 35.5 A : B : C : D : t : 10 sec or more required 80 4 56 DOWN 2.5 sec or more required SEL.
0.5 0.6 0.7 F 200 V Black COM (0 V) G Shield Data A phase output pulse Connector pin arrangement B phase output pulse G A F B H E D C 0 1 2 3 4 3 2 1 Counter value 10-12-55
B A B A B A B A B A B A B A B A B 40 50 63 80 100 6 4 3.5 1.5 0 0.5 6.5 2 4 11.5 10 0 0 4.5 0 2 9.5 8 ML2B 3.5 1.5 0 0.5 6.5 2 4 11.5 10 0 0 4.5 0 2 9.5 8 8.5 7.5 6 5 2.5 3 9 4.5 6.5 14 12.5 1.5 2 8 3.5 5.5 13 11.5 12 10 9.5 7.5 6 6.5 4.5 8 10 17.5 16 4 4.5 12.5 6 8 15.5 14 13.5 12.5 11 10 7.5 8 14 9.5 11.5 19 17.5 6.5 7 13 8.5 10.5 18 16.5 D-A9 and D-A9V cannot be mounted on 50.
GC SB + Stroke B ZZ + Stroke A + Stroke B SA + Stroke A 63 SZ + Stroke B Front mounting flange C port A, B port B port A 20 C port A port A ' View A-A' GC SB + Stroke B ZZ + Stroke A + Stroke B SA + Stroke A 41 Made to Order Specifications Series MGG Auto Switch Rail Mounting 8 MGG XC13 Bearing type Mounting type Stroke Auto switch type Auto switch symbol Bore size Auto switch rail mounting
Only reading is available Reading and writing are available 5.3 Setting and checking HRS090 Series 5-10 HRX-OM-T004 Chapter 5 Simple communication protocol function 5.4 Communication sequence Starts with a request message from the customers system (host), and finishes with a response message from the product (slave). This product operates as a slave. It does not send any requests.
Only reading is available Reading and writing are available 5.3 Setting and checking HRSH Series 5-10 HRX-OM-R028 Chapter 5 Simple communication protocol function 5.4 Communication sequence Starts with a request message from the customers system (host), and finishes with a response message from the product (slave). This product operates as a slave. It does not send any requests.
LCD 4.DIN 30mm 30mm 10 - 2-2 30mm No. 2-3 (1), (Err6), 1 ML2B25 15 ML2B32 19 ML2B40 24 2-4 5mm 5-10-15 5mm Err5 4.2 5 10 15 20 1.0 1.0 1.0 1.0 5.8 5mm30mm Err6: 20 30 100mm/sec :50cm :0.5MPa 11 - 3 3 3 3 ML2B+CEU2 NO 1 () () YES NO () YES NO YES YES NO YES NO YES YES NO NO NO YES A 12 - A 1.
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
A 6% reduction of industrial CO emissions from 1990 levels is targeted for 2010. However, presentation of a plan for 10% or more reduction will be demanded.
Series 10-/11-/12-/13Clean Series Available for clean environment. Particle generation in a clean room can be prevented.
Series 10-/11-/12-/13Clean Series Available for clean environment. Particle generation in a clean room can be prevented.
Series 10-/11-/12-/13Clean Series Available for clean environment. Particle generation in a clean room can be prevented.
Series 10-/11-/12-/13Clean Series Available for clean environment. Particle generation in a clean room can be prevented.