ZR Relief port (10-, 21-) Vacuum port (11-, 22-) H1 MM FZ FX Relief port (20, 25) Eh8 D I 20 to 32 Width across flats KA 1.5 A AL K Standard port Relief port (32, 40) Width across flats NA 4 x FD 45 FT F ZZ + Stroke Z + Stroke S + Stroke H FY 40 (mm) 12 10 8 6 KA MM NA NN B1 B2 Bore size 4 7 FD E 20-0.033 0 13 8 AL D K 52 40 40 34 B FX FZ FY G FT 46.5 37.5 33.5 28 FL Z H H2 H1 S P I F C2 A ZZ
MM Relief port FX 20, 25 Eh8 D FZ I 20 to 32 Standard port Relief port Width across flats NA 4-FD 45 1.5 AL 32, 40 A F N K N S + Stroke FT H FY Z + Stroke ZZ + Stroke 40 (mm) 4 7 FD E 20-0.033 0 52 40 40 34 B FX FZ FY G FT 13 8 AL D K MM NA NN B1 B2 Bore size ZZ Z H H2 H1 S P N I F C2 A 66 60 60 60 75 75 75 11 8 8 8 40 32 25 20 24 22 22 18 50 45 45 41 8 8 8 6 6 5 22 17 17 13 41 32 32 26
of short shaft length Change of double shaft length Change of short shaft length Change of double shaft length XA45 CRA1 XA46 XA47 XA48 CRQ2 Y Y Y Y Y XA49 XA50 MSQ K K, T K K J K K K J K, T K K XA51 K K J J J K K J J J K K K J J J J XA52 MSZ XA53 J J J J J J J XA55 CRQ2X MSQX J XA57 J Reversed shaft, Change of double shaft length A combination
Form w 1 Material e Buffer spec. r Buffer stroke t Vacuum inlet Flat Type with Groove A 3 30.5 11 1.2 11 04 6 37 14 14.5 10 47 18 20.5 J K Width across flats E 3 30.5 11 1.8 11 6 37 14 14.5 10 47 18 20.5 06 08 N S U F GN GS HS 7 15 55 36.5 1.2 10 20 62.5 44 06 08 15 55 36.5 1.8 20 62.5 44 04 JB K ZP3 T UM B5 C2 3 31.5 12 11 J K 10 6 38 15 14.5 10 48 19 20.5 JB K 15 56 37.5 10 20 63.5 45 10
10, 15, 20, 30, 40 MRQ K J XA39 XA40 XA41 XA45 K K K XA46 Y Y Y Y Y 20, 30, 40 Y J K K, T K, T K 10, 15, 20, 30, 40 K K K K, T K Z X X, Z J J J, Z Z J 20, 30, 40 Z J 10, 15, 20, 30, 40 T J Reversed shaft, Change of double shaft length X 20, 30, 40 Reversed shaft, Change of double shaft length Combination Chart of Made to Order Chart 4.
10, 15, 20, 30, 40 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 K 20, 30, 40 CRA1 10, 15, 20, 30, 40 CRQ2 20, 30, 40 MSQ XA38 K 10, 15, 20, 30, 40 K J XA45 K K MRQ DCombination Chart of Made to Order 20Chart 4.
1.0 Communication speed [bps] 156 k/625 k/2.5 M /5 M/10 M 125 k/250 k/500 k 9.6 k/19.2 k/45.45 k/ 93.75 k/187.5 k/500 k/ 1.5 M/3 M/6 M/12 M 10 M/100 M Configuration file Note 2) EDS file GSD file EDS file Communication specifications Input 896 points 108 words 4 stations occupied (8 times setting) Input 200 bytes Output 200 bytes Input 57 words Output 57 words Input 256 bytes Output 256
Symbol Maximum ambient Rod boot material temperature One side Both sides J JJ 70C Nylon tarpaulin Symbol Specifications K KK 110C Heat resistant tarpaulin -XA Change of rod end shape Mounting Bracket Part No. Maximum ambient temperature for the rod boot itself.
Cushion Suffix for cylinder Nil N F Lube type Non-lube type Steel tube J K N R H Nil Nylon tarpaulin Heat resistant tarpaulin Without cushion With cushion on rod end With cushion on head end With cushion on both ends Rod boot D Cushion T Except tubing I.D. 40 Auto switch is not mountable. When specifying symbol more than one, combine symbols in alphabetically.
Cushion Suffix for cylinder Nil N F Lube type Non-lube type Steel tube J K N R H Nil Nylon tarpaulin Heat resistant tarpaulin Without cushion With cushion on rod end With cushion on head end With cushion on both ends Rod boot D Cushion T Except tubing I.D. 40 Auto switch is not mountable. When specifying symbol more than one, combine symbols in alphabetically.
J 70C Nylon tarpaulin K 110C* Neoprene cloth * Maximum ambient temperature for the rod boot only. Mounting Bracket Part No.
Type: Pressure Monitor, Sensor, Monitor Structure: Integrated, Output Method: Analog, Pipe Port Type: [Threads] Male thread, Plumbing Thread Type: [Rc (R)] R, Pressure Resistant(kPa): 100, Operating Temperature Range(°C): 18~28, Response Differential(kPa): ±3, Pipe Connection Direction: Back, Plumbing Thread Nominal: [1/8] 1/8, Rated Pressure Range(kPa): -100 to 0, Compatible Fluid: Air,
Specifications: None, Display Pressure: -100 to 0 kPa, Connection Thread: 01 (R 1/8)
Select the graph that corresponds to the imaginary stroke l. l k Imaginary stroke l = (Stroke) + k + l k: Distance between the center and end of the plate 6 (Example) 1. When using CXSJM6-10 and l = 15 mm: Imaginary stroke l = 10 + 2.75 + 15 = 27.75 Therefore, the graph used for your model selection should be the one for CXSJM6-30 (6) ). 2.75 mm 10 4 mm 15 5 mm 20 6 mm 25 2.
Select the graph that corresponds to the imaginary stroke l. l k Imaginary stroke l = (Stroke) + k + l k: Distance between the center and end of the plate 6 (Example) 1. When using CXSJM6-10 and l = 15 mm: Imaginary stroke l = 10 + 2.75 + 15 = 27.75 Therefore, the graph used for your model selection should be the one for CXSJM6-30 (6) ). 2.75 mm 10 4 mm 15 5 mm 20 6 mm 25 2.
L k Imaginary stroke L' = (Stroke) + k + L k: Distance between the center and end of the plate 6 (Example) q When using CXSJM6-10 and L = 15 mm: Imaginary stroke L' = 10 + 2.75 + 15 = 27.75 Therefore, the graph used for your model selection should be the one for CXSJM6-30 6 ). 2.75 mm 10 4 mm 15 5 mm 20 6 mm 25 w When using CXSJL25-50 and L = 10 mm: Imaginary stroke L' = 50 + 6 + 15 = 71
L k Imaginary stroke L' = (Stroke) + k + L k: Distance between the center and end of the plate 6 (Example) q When using CXSJM6-10 and L = 15 mm: Imaginary stroke L' = 10 + 2.75 + 15 = 27.75 Therefore, the graph used for your model selection should be the one for CXSJM6-30 6 ). 2.75 mm 10 4 mm 15 5 mm 20 6 mm 25 w When using CXSJL25-50 and L = 10 mm: Imaginary stroke L' = 50 + 6 + 15 = 71
V V K* K* K* -XA46 -XA51 Change of long shaft length (Without keyway) V V V V T, J, K* K* T, K* J* K* MSQ MSZ CRQ2X MSQX -XA52 Change of short shaft length (Without keyway) V V K* K* K* -XA53 Change of double shaft length (Both without keyway) V V V K* -XA54 Change of long shaft length (With four chamfers) V V V X, Z* X, Z* -XA55 Change of short shaft length (With four chamfers)
K V 1 10 XLA S P1P2 XL XL Conductances combined When each of the separate conductances are given as C1, C2 and Cn, the composite conductance C is expressed as: C=1/(1/C1+1/C2++1/Cn) when in series, and C=C1+C2++Cn, when in parallel.