q"s tuoe) 2 1/4 (1000. 2000 tvoe) 3/8 (2000 type) Without bracket I Flat bracket L-bracket World Wide QS\E Support...
L1 L2+A5 L3 2 1 W V 2 E= ( ) 2 9.8 1000 Collision speed V=1.4 Va *) Corrected coeficient 1 420 E= 1( ) =0.088 2 1000 V=1.4 X 300=420 Calculate kinetic energy E (J) of work. Calculate allwable kinetic energy Ea (J). Check that kinetic energy of work does not exceed allowable kinetic energy.
SUP = 0.2 MPa 0.2 0.2 0.2 0.1 0.1 0.1 0 0 0 50 100 150 200 0 Discharge (mL/min) 0 Discharge (mL/min) 200 400 600 800 1000 0 Discharge (mL/min) 200 400 600 800 1000 Air Consumption: Built-in Solenoid Valve/Air Operated Calculation of Air Consumption Air Consumption 45 Find the air consumption for operation with a 5 Hz switching cycle and pilot air pressure of 0.35 MPa from the air consumption
Mr = 1 x 9.8 (30 + 10.5)/1000 = 0.39 A6 = 10.5 Mar = 36 Mrmax = 36 K = 1 = 1 '2 = 0.39/36 = 0.011 Examine My. My = 1 x 9.8 (10 + 30)/1000 = 0.39 A3 = 30 May = 1 x 1 x 18 = 18 Mymax = 18 K = 1 = 1 2 = 0.39/18 = 0.022 M = W x 9.8 (Ln + An)/1000 Correction value of moment center position distance An: Table (3) Find the static moment M (Nm).
Up to 2000 Up to 2000 Up to 600 Up to 800 Up to 1000 Up to 2000 Up to 2500 Up to 3000 Up to 400 Up to 600 Up to 800 Up to 1000 10 20 45 60 Guide Rod Slider High Rigidity Slider Type Step Motor (Servo/24 VDC) AC Servo Motor Belt drive Belt drive Series LEJB Ball screw drive Series LEL Series LEJS CAT.ES100-101 CAT.ES100-104 Sliding bearing Series LEL25M Ball bushing bearing Series LEL25L
Bore size Series MB, CA2 Pressure 0.5 MPa Load factor 50% Stroke 500 mm Series CS1/CS2 Pressure 0.5 MPa Load factor 50% Cylinder stroke 1000 mm Average speed (mm/s) System 40 50 63 80 100 125 140 160 180 200 1000 Perpendicular, upward actuation Horizontal actuation 900 800 700 600 500 400 300 200 100 0 A 1000 900 800 700 600 500 400 300 200 100 0 B System Components It is when the cylinder
Operating pressure: 1 MPa Lateral load 1000 Stroke 100 Eccentric distance 100 80 Load weight (kg) 1000 63 10 50 40 32 25 20 1.0 100 Allowable lateral load (N) 0.1 10 100 1000 Maximum piston speed (mm/s) 100 80 63 50 40 10 32 25 20 1 0 50 100 150 200 Stroke + Eccentric distance (mm) Refer to Model Selection in Best Pneumatics No.2 for details about model selection procedure. 3 ISO Standards
Bore size Series MB Pressure 0.5 MPa Load factor 50% Stroke 500 mm Series CS1 Pressure 0.5 MPa Load factor 50% Cylinder stroke 1000 mm 50 63 80 100 125 140 160 180 200 250 300 Average speed (mm/s) Series 1000 1100 Perpendicular, upward actuation 900 Horizontal actuation 800 700 600 500 400 300 200 100 VK VQ7-8-FG-S-A03 VQ7-8-FG-S-RA03 VZ VF 0 1000 1100 VFR 900 800 700 600 500 400 300 200
Graph (7) Air Consumption of Tube or Steel Pipe (For one cycle) Graph (8) Required Air Volume of Cylinder and Piping 1000 1000 1000 1000 100 100 100 100 Air consumption (l(ANR)) Piping length (inch) Air consumption (l(ANR)) 10 10 Required air volume (l /min (ANR)) Max. piston speed (inch/s) Required air volume (l/min (ANR)) Bore size (in) Tube I.D.
To Travel amount per 1 command pulse (P=1m) by actuator lead (L = 6mm) and pulley ratio (n1/n2 = 1/1) = 1 1048576 1 1000 Pn210 Pn20E 1 6 1/1 = 1048576 Pn210 Pn20E 6 1000 1 = 1048576 Pn210 Pn20E 6000 1 = 65536 Pn210 Pn20E 375 1 *1 For pulley ratio, refer to Lead of LECYM Operation Manual (Simplified Edition),section 4.4.1.
To Travel amount per 1 command pulse (P=1m) by actuator lead (L = 6mm) and pulley ratio (n1/n2 = 1/1) = 1 1048576 1 1000 Pn210 Pn20E 1 6 1/1 = 1048576 Pn210 Pn20E 6 1000 1 = 1048576 Pn210 Pn20E 6000 1 = 65536 Pn210 Pn20E 375 1 *1 For pulley ratio, refer to Lead of LECYU Operation Manual (Simplified Edition),section 4.4.1.
Modbus RTU protocol (Hexadecimal notation) Request data 01 08 0 1234 ED7C Response data (normal response) 01 08 0 1234 ED7C (Binary notation) Response data 0001 1000 0 0 0001 0010 0011 0100 1110 1101 0111 1100 Response data (normal response) 0001 1000 0 0 0001 0010 0011 0100 1110 1101 0111 1100 For correspondence between ASCII notation and ASCII hexadecimal notation, refer to the 8.4 ASCII
A Q value of approximately 620 Nl/min is obtained. 1500 2000 1500 2000 4.The 620 Nl/min.theoretical value is multiplied by 1.4 Q = 620 Nl/min. 1.4 Q = 870 Nl/min. 160 1000 1000 Maximum air consumption Q [Nl/min.]
Mr = 1 x 9.8 (30 + 10.5)/1000 = 0.39 A = 10.5 Examine My. My = 1 x 9.8 (10 + 30)/1000 = 0.39 A3 = 30 Find the static moment M (Nm). M = W x 9.8 (Ln + An)/1000 Corrected value of moment center position distance An: Table 3 Find the allowable static moment Ma (Nm).
1l'" Immj 32 -700 50 7 5 10 64 72 32 36 79 90 25 31 ", 40 -800 55 9 7 10 Cushi()(\ vl\lve Port 4 50 -1000 70 9 12 12 90 45 50 110 120 36,S 39.5 63 1000 80 9 12 12 100 80 1000 100 12 14 16 126 63 153 45.5 J()a, -1000 120 14 1 6 I. 150 75 176 54 FE FT Head Iionge/ (G) Head flange 101m) ' ~," BoreSiW .
20 to 1000 35 32 70 27 81 108 1/4 1/4 52 20 40 95 17 27 59 13 12 11 M8 x 1.25 7 18 80 63 Up to 1000 20 to 1000 35 32 86 27 101 115 1/4 1/4 64 20 40 102 17 26 67 18 15 11 M10 x 1.25 7 18 99 80 Up to 1000 20 to 1000 40 37 102 32 119 129 1/4 1/4 78 25 52 113 21 30 72 23 17 13 M12 x 1.75 10 22 117 100 Up to 1000 20 to 1000 40 37 116 41 133 140 1/4 1/4 92 30 52 124 21 31 76 25 19 16 M12 x 1.75
Cylinder speed 1000 mm/sec. Sequencer response time 0.1 sec. Detecting point dispersion Within 100 mm (= 1000 mm/sec. x 0.1 sec.) Take PLC response time into consideration when using.
Cylinder speed 1000 mm/sec. Sequencer response time 0.1 sec. Detecting point dispersion Within 100 mm (= 1000 mm/sec. x 0.1 sec.) Take PLC response time into consideration when using.
Cylinder speed 1000 mm/sec. Sequencer response time 0.1 sec. Detecting point dispersion Within 100 mm (= 1000 mm/sec. x 0.1 sec.) Take PLC response time into consideration when using.
Cylinder speed 1000 mm/sec. Sequencer response time 0.1 sec. Detecting point dispersion Within 100 mm (= 1000 mm/sec. x 0.1 sec.) Take PLC response time into consideration when using.