Air Cylinder/End Lock Series MBB ø32, ø40, ø50, ø63, ø80, ø100 32 40 50 63 80 100 up to 700 25 79 32 64 10 3 7 50 C85 up to 800 31 90 36 72 10 3 9 55 up to 1000 38.5 110 45 90 12 2 9 70 Fd FY B CG1 up to 1000 39.5 120 50 100 12 2 9 80 up to 1000 45.5 153 63 126 16 4 12 100 up to 1000 54 178 75 150 16 4 14 120 FX FE FT MB FZ C95 Rear flange(G)/Locking at head end (Hl) Hl/ Rl Wl (mm) CA1 Cushion valve Stroke range Bore size (mm) ZZ ZZ FZ FY FX FT FD B
100, 200, 300, 400, 500, 600, 700, 800, 900, 1000 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000 25 32 40 2000 2000 2000 *When the required stroke is longer than the standard stroke , refer to the specifications for Made to Order q (p.5.4-79) longer stroke styles.
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 40 50 63 80 100 125 140 160 180 200 Average speed (mm/s) System VK 1000 Perpendicular, upward actuation Horizontal actuation 900 800 700 600 500 400 300 200 100 VZ A VF VFR 0 1000 VP4 Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco,
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
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).
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.
L/min(PFMC7501) [ P_1] OUT1 [ 500] 500 L/min(PFMC7102) 29 [F 1] [ 1000] 1000 L/min(PFMC7202) [ 25] 25 L/min(PFMC7501) [ H_1] OUT1 [ 50] 50 L/min(PFMC7102) [ 100] 100 L/min(PFMC7202) [ CoL] OUT1 [SoG] ONOFF [ oU2] OUT2 2 [ HYS] [ 2ot] OUT2 2 [ 2_P] [ 250] 250 L/min(PFMC7501) [ P_2] OUT2 2 [ 500] 500 L/min(PFMC7102) 37 [F 2] [ 1000] 1000 L/min(PFMC7202) [ 25] 25 L/min(PFMC7501) [ H_2] OUT2