%silltr 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).
Step Axis Movement mode Speed Position Acceleration Deceleration Pushing force Trigger LV Pushing speed Moving force Area 1 Area 2 In position Comments mm/s mm mm/s2 mm/s2 mm mm mm Axis 1 ABS 500 100.00 3000 3000 0 85.0 50 100.0 10.0 30.0 0.5 Axis 2 ABS 500 100.00 3000 3000 0 85.0 50 100.0 10.0 30.0 0.5 0 Axis 3 ABS 500 100.00 3000 3000 0 85.0 50 100.0 10.0 30.0 0.5 Axis 1 INC 500 200.00
(P.12) PLC (PLC) 2 12.4 (P.50) 11.(P.42) 3.(P.12) 83 - 5.(P.23) 10.1 (P.33) 3.(P.12) PLC (PLC) 2 12.4 (P.50) () () (LED() 3.2 (P.13) ) 11.(P.42) 5 11.(P.42) 11.(P.42) 3.(P.12) (CN1: EMG 3.
Conversion unit Controller USB cable (A-miniB type connector) 120.3 120.3 mm mm 200 200 mm/s mm/s Communication 100 500 100 500 1 1 200 1000 200 1000 2 2 CN4 50 200 50 200 3 3 cable PC (The PC should be obtained separately.) Controller PLC, etc.
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).
Movement Speed Position Acceleration Deceleration Area 1 Area 2 In pos force Force speed force 2 2 mode mm/s mm mm/s mm/s mm mm mm Value mm/s 0 1 Absolute 100 100.00 1000 1000 50 40 10 100 0 0 5 2 Absolute 50 50.00 1000 1000 0 0 0 100 0 0 0.1 () (1)No.
LE C A 6 N A (DC24V) (LE ) LESH16RAJ-50BS-R16N1D 6 64 LESH16RAJ-50 I/O N NPN DIN P PNP 1 1.5m D DIN 3 3m 5 5m <> NPNPNP LESH16RAJ-50 NPN NPN 7 - 2.3 1 I/O LEC-CN5-* PLC 1 3 DC24V CN5 CN3 CN4 2 1 () LE-CA-* CN2 120.3 120.3 mm mm 200 200 mm/s mm/s 100 500 100 500 1 1 200 1000 200 1000 2 2 3 50 200 50 200 3 3 CN1 DC24V <> AWG20 (0.5mm 2) USB A-miniB type USB LEC-W2
(OUT05)OFF 11INPOFF ... 12BUSY ON 0mm 50mm 60mm 100mm 5 13DRIVEOFF 14No.2 ON (OUT1ON) 15INPON 16BUSYOFF 10mm 57 - 13.2 100mm/s 100mm (No.1 ) 100mm ,10mm/s 50% 5mm (INPON )50mm/s 50mm (No.2 ) No. 1 2 2 2 mm/s mm mm/s mm/s mm mm mm mm/s 0 1 ABS 100 100.00 1000 1000 50 40 10 100 0 0 5 2 ABS 50 50.00 1000 1000 0 0 0 100 0 0 0.1 () 1No.1(IN0ON) / 2DRIVEON (2)(5)(10)(13) No.1
Basic 1.2 1.62 2.04 3.2 Basic weight Axial foot 1.44 1.88 2.44 3.72 Flange 1.29 1.79 2.23 3.47 Weight for additional stroke per 50mm 0.06 0.08 0.09 0.15 Calculation example: RHCL32-600 PBasic weight 2.44 (Foot style 32) PBasic weight 0.09/50 Stroke PCylinder stroke600 Stroke 2.44+0.09 X 100/50=2.62kg 4.10-5 High Power Cylinder Series RHC Front flange Rc(PT)P GB Rc(PT)P GA 4-R chamfer 4-FD
(Min. 50 mm). Risk of electric shock, wire break, contact failure and loss of control for the product can happen if Standard cables are used in case of inflecting the cables repeatedly. (10) Confirm proper wiring of the product.
B 2 2(B) 4(A) B Elbow fitting assembly (Downward) B4: 4 elbow fitting assembly B6: 6 elbow fitting assembly 1(P) 5(EA) 3(EB) A 4 4 position dual 3 port valve: N.C./N.O.
, 63 CY1S, CY1L: 6 to 40 12, 16, 20 25, 32, 40 50, 63, 80 100 12, 16, 20 25, 32, 40 50, 63, 80 100 6, 10 15, 20 25, 32 12, 16 20, 25 32, 40 20, 25 32, 40 50, 63 32, 40 50, 63 80, 100 6, 10 16, 20 25, 32 12, 16 20, 25 6, 10 16 20, 25, 32 40, 50 10, 15 25 10, 16, 20 25, 32 6, 10 16 20, 25 32, 45 Bore size (mm) 5 to 50 mm/s 7 to 50 mm/s 5 to 50 mm/s 5 to 50 mm/s Piston speed Air cushion on both
= 2, 4, 6, 8 110 + 50 (n 2) n = 2, 4, 6, 8 Same side 1 10 90 100 110 20 90 100 110 75 90 100 110 Different sides With 2 Same side (n 2) 2 90 + 50 (n 4) 2 n = 4, 8, 12, 16 100 + 50 (n 4) 2 n = 4, 8, 12, 16 100 + 50 (n 4) 2 n = 4, 8, 12, 16 20 + 50 n = 2, 4, 6, 8 Different sides D-B59W With n 75 + 50(n 2) n = 2, 3, 4 90 + 50(n 2) n = 2, 4, 6, 8 100 + 50 (n 2) n = 2, 4, 6, 8 110 + 50
0.000 20 40 60 0.000 25 50 75 100 125 Load [N] Load [N] Load [N] LESYH16 LESYH16 Lr = 120 mm LESYH16 0.50 0.3 0.08 Table displacement [mm] Table displacement [mm] Table displacement [mm] LESYH16 -100 LESYH16 -100 LESYH16 -100 0.40 0.06 0.2 0.30 LESYH16 -50 0.04 LESYH16 -50 0.20 LESYH16 -50 0.1 0.02 0.10 0.000 100 200 300 400 0.000 50 100 150 200 0.00 50 100 150 200 Load [N] Load [N] Load