Vacuum (mm) 02_o2 0 4 _ o 4 0 6 0 6 0 8 _ 0 8 10 _ o.10 1 3 @ 1 3 1 6 @ 1 6 20 @2O 25 _ a25 32 _ a32 40 s4O 50 o50 Pad dia. (mm) 02_o2 0 4 o 4 0 6 a 6 0 8 0 8 1 0 _ o 1 0 1 3 _ o 1 3 1 6 _ s 1 6 20 szo 25 o25 32 s32 40 s4O 50 650 Thread Dia. s2-sB o4(}o50 B4 M4 x 0.7 o B5 M5 x 0.8 o a Thread B6 M G x l a o B8 M8 x 1.25 o a 8 1 0M 1 0 x 1 . 2 5 o o .
(mm) 02_o2 0 4 _ o 4 0 6 0 6 0 8 _ 0 8 10 _ o.10 1 3 @ 1 3 1 6 @ 1 6 20 @2O 25 _ a25 32 _ a32 40 s4O 50 o50 Pad dia. (mm) 02_o2 0 4 o 4 0 6 a 6 0 8 0 8 1 0 _ o 1 0 1 3 _ o 1 3 1 6 _ s 1 6 20 szo 25 o25 32 s32 40 s4O 50 650 Thread Dia. s2-sB o4(}o50 B4 M4 x 0.7 o B5 M5 x 0.8 o a Thread B6 M G x l a o B8 M8 x 1.25 o a 8 1 0M 1 0 x 1 . 2 5 o o .
HS 8.5 SMC SMC SMC SMC 16 16 A 29 Auto switch B A 26 Auto switch B (36) D-B5/B6/B59W type 20 to 40 D-G5NTL type 20 to 40 50 to 100 50 to 100 Approx. HS Approx. HS 12 12 SMC SMC 24.5 24.5 A 33 B A 33 Auto switch B D-C73C/C80C type 20 to 40 D-H7C type 20 to 40 50 to 63 50 to 63 Approx. HS Approx.
Note Description C6: With One-touch fitting for 6 C8: With One-touch fitting for 8 L6: With One-touch fitting for 6 (Elbow fetching upward) L8: With One-touch fitting for 8 (Elbow fetching upward) B6: With One-touch fitting for 6 (Elbow fetching downward) B8: With One-touch fitting for 8 (Elbow fetching downward) q SUP/EXH block assembly SZ3000-50-1Aw e r t y u SZ3000-53-5A SX3000-113-1 SZ3000
Note Description C6: With One-touch fitting for 6 C8: With One-touch fitting for 8 L6: With One-touch fitting for 6 (Elbow fetching upward) L8: With One-touch fitting for 8 (Elbow fetching upward) B6: With One-touch fitting for 6 (Elbow fetching downward) B8: With One-touch fitting for 8 (Elbow fetching downward) q SUP/EXH block assembly SZ3000-50-1Aw e r t y u SZ3000-53-5A SX3000-113-1 SZ3000
"n" pcs. 90 Same side 120 75 (n 4) 2 (n 4) 2 (n 2) 2 120 + 50 15 + 50 90 + 50 Different sides n = 2, 4, 6, 8 n = 4, 8, 12, 16 n = 4, 6, 8 D-B5, D-B6 (n 2) 2 (n 2) 2 90 + 50 120 + 50 75 + 50 (n 2) Same side n = 2, 3, 4 n = 2, 4, 6, 8 n = 2, 4, 6, 8 90 1 pc. 120 10 120 Different sides 20 90 2 pcs. "n" pcs.
Arrange so that maximum load will be 40% for theoretical force of 20, 50% for 32, 55% for 40 and 60% or less for 50, respectively.
, 75, 100, 125, 150, 200 201 to 350 301 to 400 301 to 450 301 to 800 D-C7/C8 D-B5/B6 D-H7 D-G5NTL 1500 10 mm 15 mm 25, 50, 75, 100, 125, 150, 200, 250, 300 D-B59W 15 mm 20 mm Note 1) Intermediate strokes other than the above are produced upon receipt of order.
12.0 0.5 Axis 3 Absolute 50 100.00 1000 1000 0 0 30 100 6.0 12.0 0.5 Axis 1 Relative 500 800.00 1000 1000 50 50 35 100 0 0 10.0 1 Axis 2 Relative 500 900.00 1000 1000 50 50 35 100 0 0 10.0 Axis 3 Relative 500 900.00 1000 1000 50 50 35 100 0 0 10.0 Step Data details Description Input range Explanation Step No. 0 to 2047 Number of step data. 3 lines (4 lines partially) of data per step.
Axis 3 ABS 50 50.00 1000 1000 0 0 0 0.5 Axis 4 ABS 50 50.00 1000 1000 0 0 0 0.5 Movement (ex.)
50 50.00 1000 1000 0 0 0 0.5 2 Axis 3 Absolute 50 50.00 1000 1000 0 0 0 0.5 Axis 4 Absolute 50 50.00 1000 1000 0 0 0 0.5 Movement (ex.)
, 75, 100, 125, 150, 200 201 to 350 301 to 400 301 to 450 301 to 800 D-C7/C8 D-B5/B6 D-H7 D-G5NTL 1500 10 mm 15 mm 25, 50, 75, 100, 125, 150, 200, 250, 300 D-B59W 15 mm 20 mm Note 1) Intermediate strokes other than the above are produced upon receipt of order.
10.00 1000 1000 0 0 0 0.5 2 INC 50 10.00 1000 1000 0 0 0 0.5 2 3 INC 50 10.00 1000 1000 0 0 0 0.5 4 INC 50 10.00 1000 1000 0 0 0 0.5 57 No.SFOD-OMT0009CN-B () ... ...
0 0 0 0.5 4 INC 50 10.00 1000 1000 0 0 0 0.5 -57No.JXC-OMT0001CN-C () ... ...
A flow of 600 l/min through an "y ot 12 mm" corresponds with a llow of ff = 50 l/min through an quivalent section of 1 mm'?. We need this conversion for the use of the diagram of lig. 3.9. We now follow the curve starting ai 7 bar until it intersects with th6 vertical line tor 50 l/min. A horizontal line towards the Dressure scale indicates about 6.3 bar.
A flow of 600 l/min through an "y ot 12 mm" corresponds with a llow of ff = 50 l/min through an quivalent section of 1 mm'?. We need this conversion for the use of the diagram of lig. 3.9. We now follow the curve starting ai 7 bar until it intersects with th6 vertical line tor 50 l/min. A horizontal line towards the Dressure scale indicates about 6.3 bar.
From the 100 mm point, the actuator must start a pushing operation of 10 mm/s speed and 50% or less force. (the pushing distance is up to 5 mm). Then, the actuator should move from the position where the pushing operation was completed (where INP turned ON) to a point 50 mm away at 50 mm/s. (Step Data No.2 is used for this operation).
From the 100 mm point, the actuator must start a pushing operation of 10 mm/s speed and 50% or less force. (the pushing distance is up to 5 mm). Then, the actuator should move from the position where the pushing operation was completed (where INP turned ON) to a point 50 mm away at 50 mm/s. (Step Data No.2 is used for this operation).
Unit: mm Piston speed (mm/s) Lock style 50 100 300 500 In terms of specific load conditions, the allowable kinetic energy indicated in the table above is equivalent to a 50% load ratio at 0.5MPa, and a piston speed of 300mm/sec.
From the 100 mm point, the actuator must start a pushing operation of 10 mm/s speed and 50% or less force. (the pushing distance is up to 5 mm). Then, the actuator should move from the position where the pushing operation was completed (where INP turned ON) to a point 50 mm away at 50 mm/s. (Step Data No.2 is used for this operation).