VQ5000 213 121.3 91.5 13.5 2(B) port 59.5 53 4 (A) port17.5 13.5 2(B) port 59.5 4(A) port 17.5 Indicator light SMC 2 4 2 4 SMC A B A B 53 40 66 162 50 41 37 31.5 18 53 40 66 B A A B Manual override 1 3 5 14 12 14 5 1 3 12 53 2-6.5 Mounting hole 35 2-6.5 Mounting hole 35 53 Manual override 18 31.5 37 41 50 98 PE X PE X P R1 R2 R2 R1 P 27.5 27.5 41 41 Rc 1/8 PE port Rc 1/8 External pilot port Rc
FL1 (A) F1 K (mm) (H) A F1 H FL1 16.5 K 3 Bore size Stroke range 24 32 40 51 21 Up to 1000 22 18 54.5 3 22.5 Up to 1000 : Same as the standard model. 1896
Load (kg) Note: 1 Nm = 0.7375 ftlb 1 kg = 2.2046 lb 1 in = 25.4 mm W1 W W m Moment (Nm) M = F x L M = F x L M = F x L F3 F2 F1 L2 L1 L3
Mitsubishi Electric Corp.: MELSECNET MINI-S3 Data Link System B Special specifications OMRON Corp.: SYSBUS Wire System C SHARP Corp.: Satellite I/O Link System D Matsushita Electric Works, Ltd.: MEWNET-F System E NKE Corp.: Uni-wire System (16 points output) F1 When creating the special specifications, complete the stations table on the right.
Page 53 Dimensions . Page 54 Model Selection . Page 41 How to Order . Page 56 Specications . Page 57 Construction . Page 58 Dimensions . Page 59 Auto Switch . Page 61 Specic Product Precautions . Page 64 Electric Actuator/Rod Type Series LEY Electric Actuator/Guide Rod Type Series LEYG Model Selection . Page 67 How to Order . Page 73 Specications . Page 75 Construction .
Load mass (kg) m1 m2 Moment (Nm) m3 M3 = F3 x L3 F3 F2 M1 = F1 x L1 F1 M2 = F2 x L2 L2 L1 L3 Calculation of Guide Load Factor 1) Maximum load mass (1), static moment (2), and dynamic moment (3) (at the time of impact with stopper) must be examined for the selection calculations. To evaluate, use a (average speed) for (1) and (2), and (collision speed = 1.4a) for (3).
Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com CX Load weight (kg) Dm1 -X 20m2 m3 Moment (Nm) Data M3=F3 x L3 F3 F2 M1=F1 x L1 F1 M2=F2 x L2 L2 L1 L3
OFF state { A R1 (Exhaust air) P B (Supply air) F1 < F2 condition: See figure q. ON state { { Immediately after turning on F1 > F2: See figure e.
Gripping point L (mm) Gripping point L (mm) F1 F1 532 MHR3/MDHR3 Series Rotary Actuated Air Gripper 3-Finger Type Construction q !
F1 F1 12-5-20 21 3 Finger Rotary Actuated Air Gripper Series MHR3/MDHR3 Construction !
F1 Holding point L (mm) Holding point L (mm) F1 2.3-19 3 Finger Air Gripper Series MHR3/MDHR3 Construction MHR3 !
No.PS-OMU0005CN-C // ZSE20B(F) ISE20B 2 8 10 11 15 15 17 20 [] 23 24 3 25 27 29 29 29 F0 31 F1 OUT1 32 F1 OUT2 35 F3 37 F4 38 F5 FUNC 40 F6 42 F10 43 F11 49 F80 50 F81 51 F82 53 F90 54 F96 56 F97 57 F98 59 F99 61 62 66 66 67 76 76 79 -1No.PS-OMU0005CN-C (ISO/IEC)(JIS) *1) *2) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO
No.PF-OMS0001CN-A // PFMC7501 PFMC7102 PFMC7202 2 10 11 12 14 15 17 18 [] 22 OU1OUT2 {3 ] 23 [] 25 26 F0 27 F1 OUT1 29 F2 OUT2 37 F3 42 F10 43 F20 47 F22 48 F30 49 F31 50 F80 OFF 51 F81 52 F82 53 F90 54 F98 56 F99 57 58 62 63 65 66 66 69 71 -1No.PF-OMS0001CN-A (ISO/IEC)(JIS) *1) *2) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO
determination F3 D 1.6 x P WB Inclined operation W + WB WV P PV W + WB WV P PV Allowable driving force table (Fn) (n=1,2,3) Determination of allowable load weight & pressure F1 = x (W + WB) x 9.8 Horizontal F2 = (W + WB) x 9.8 x (COS + SIN) Inclined (Refer to page 5 for vertical operation.)
determination F3 D 1.6 x P WB Inclined operation W + WB WV P PV W + WB WV P PV Allowable driving force table (Fn) (n=1,2,3) Determination of allowable load weight & pressure F1 = x (W + WB) x 9.8 Horizontal F2 = (W + WB) x 9.8 x (COS + SIN) Inclined (Refer to page 5 for vertical operation.)
No.PS-OMS0006CN-G / / ZSE20(F) ISE20 2 8 10 11 14 14 16 18 [] 20 21 3 22 24 26 26 26 F0 28 F1 OUT1 29 F3 32 F4 33 F6 35 F10 36 F11 41 F80 42 F81 43 F82 45 F90 46 F98 48 F99 49 50 54 54 55 62 62 64 -1No.PS-OMS0006CN-G *1) (ISO/IEC)(JIS) *2) *1) ISO 4414: Pneumatic fluid power -General rules relating to systems ISO 4413: Hydraulic fluid power -General rules
MY1B m2 m3 Moment (Nm) MY1M M1 = F1 x L1 F1 M2 = F2 x L2 M3 = F3 x L3 F3 F2 MY1C L2 L1 L3 MY1H 4. Accuracy Mechanically jointed rodless cylinders do not guarantee traveling parallelism. When accuracy in traveling parallelism and intermediate stroke position is required, please contact SMC sales representatives.
EXH Specifications Model Port size Specifications Model Standard specifications P1 P2 A B C D E F G H I VHS20 1/8, 1/4 1/8 66.4 22.3 40 37.5 14 46.6 33.6 28 37.5 VHS30 1/4, 3/8 1/4 80.3 29.4 53 49 19 52 38 30 49 VHS40 1/4, 3/8, 1/2 3/8 104.9 38.5 70 63 22 58 44 36 63 VHS40-06 3/4 1/2 110.4 42 75 63 22 58 44 44 63 VHS50 3/4, 1 1/2 134.3 53 90 76 26 76 61 53 81 IN, OUT EXH IN OUT OUT EXH
Series CG1Q Air Cylinder: Low Friction Type Double Acting, Single Rod With Mounting Bracket Without rod boot ZZ Axial Foot Style Axial foot style: CG1LQ Without rod boot Z Bore (mm) B LC LD LH LS LT LX LZ M W X Y 20 25 32 40 50 63 80 100 34 4 4 4 4 5 5 6 6 6 6 7 7 10 12 11 14 20 53 53 53 60 67 67 74 74 3 10 10 10 10 17.5 17.5 20 20 15 7 3 3 3 3 4.5 4.5 4.5 6 32 44 47 52 53 63.5 75.5 75.5
EXH Flow Rate Characteristics Model Port size Flow rate characteristics Model Standard specifications P1 P2 A B C D E F G H I VHS20 1/8, 1/4 1/8 66.4 22.3 40 37.5 14 46.6 33.6 28 43 VHS30 1/4, 3/8 1/4 80.3 29.4 53 49 19 52 38 30 49 VHS40 1/4, 3/8, 1/2 3/8 104.9 38.5 70 63 22 58 44 36 63 VHS40-06 3/4 1/2 110.4 42 75 63 22 58 44 44 63 VHS50 3/4, 1 1/2 134.3 53 90 76 26 76 61 53 81 IN, OUT EXH