2 Phase Stepper Motor/Without Motor Brake Series LXP Stroke + 124 Stroke + 141 Motor unit 4.5 4H9 4H9 3 6 38 34 Section C detail (Scale: 5/1) Stroke + 104 Stroke + 121 12 7.5 4-M6 x 1 4H9 E 1 5.4 8.4 4-9.5 4-5.6 50 4.5 Section C 4-M6 x 1 9 43 5.5 D 30 Cross section BB Refer to page 300 for mounting.
BS Bumper bolt (resin tipped): Plate B side or C side Shock absorber Applicable Auto Switches/Refer to pages 1575 to 1701 for further information on auto switches.
V : 150 [L] Cooled substance specific heat C : 1.0 x 103 [cal/(kgfC)] HRS 100/150 HRS 100/150 HRSH 090 HRSH Cooled substance temperature when cooling begins T0 : 30 [C] Cooled substance temperature after t hour Tt : 20 [C] Cooling temperature difference iT : 10 [C] (= T0 Tt) Cooling time it : 15 [min] Conversion factor: hours to minutes : 60 [min/h] Conversion factor: kcal/h to kW : 860
Sealant/Gasket seal P.554 P.667 P.554 P.554 M/UNF/R/NPT More space beneath the tube. Easier installation/removal of the tube.
m P 0.1 x m + m P D 1.6 x D 5.0 x D 5.0 x m m mv P Pv m > mv P > Pv Determination of allowable load mass & pressure Inclined operation (Refer to page 1548
VF1000 VF3000 VF3000 VF3000 VF3000 VF5000 VF5000 VF5000 VF5000 () P P(SUP) P A B A(CYL2) B(CYL1) A B EA EB R1(EXH2) R2(EXH1) R1 R2 (B)2 4(A) (B)2 4(A) (R2)3 1 5(R1) (P) (R2)3 1 5(R1) (P) 3(R2) 1(P) 5(R1) JIS () Z (B)2 (A)4 1:P 2:B 3:R2 4:A 5:R1 1:P(SUP) 2:B(CYL.1) 3:R2(EXH.1) 4:A(CYL.2) 5:R1(EXH.2) 1:P 4:A 2:B 5:R1 3:R2 EZTZDZLZMZ DC24V ) 8 VF1000-OMP0001 VF1000/3000/5000 VF1000/3000
S. l AR2001 2501 3001 : Max.3.5t :-t-tt ., AR4001 : Max.5.0t ~ I II; a -tp ort cenler (fJ ~ ~c=Pr r-IN j~ OUT f= 0 .bj=J ~ A * N P Q Bracket mounting dimensions Model Port size A B C 0 E F G H J K L M AR2001 1/8 1/4 40 95 17 40 35 30 34 44 5.4 15.4 55 2.3 33.5 25 8 33 AR2501 1/4 3/8 53 102.5 25 48 32 30 34 44 5.4 15.4 55 2.3 33.5 25 843 42.5 32.5
P P P R R R R DIN DIN DIN DIN ISO#:EN ISO#:EN ISO#:EN ISO#:EN-175301 175301 175301 175301-803 803 803 803C C C C( ( ( ( DIN DIN DIN DIN 43650C)( 43650C)( 43650C)( 43650C)( 8mm) 8mm) 8mm) 8mm) DIN IP65() () 90 :3.57 ()JIS.C3306 0.5mm 2 3 1(p)3R2R5R1 3(R2 3(R2 3(R2 3(R2 R) R) R) R) 5(R1) 5(R1) 5(R1) 5(R1) 1 1 1 1 P P P P) ) ) ) VQZ100/1000 KQ2H06-M5 AN120-M5 KJS04-M5 VQZ200/2000 KQ2S06
LVD Refer to the separate pamphlet P-E00-5A for further details.
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.
HRZ x V x C x iT it m x C x (T0 Tt) it Q = = HRZD 1 x 150 x 4.186 x 103 x 10 900 = = 6977 [J/s] 7.0 [kW] m x C x (T0 Tt) it x 860 x V x 60 x C x iT it x 860 HRW Q = = Cooling capacity = Considering a safety factor of 20%, 7.0 [kW] x 1.2 = HECR 1 x 150 x 60 x 1.0 x 103 x 10 15 x 860 8.4 [kW] = HEC Q x t: Heat capacity [kJ] Thermo-chiller Water bath 6977 [W] = 7.0 [kW] 20C HEB Cooling
[L] Cooled substance specific heat C : 1.0 x 103 [cal/(kgfC)] Cooled substance temperature when cooling begins T0 : 30 [C] Cooled substance temperature after t hour Tt : 20 [C] Cooling temperature difference iT : 10 [C] (= T0 Tt) Cooling time it : 15 [min] Conversion factor: hours to minutes : 60 [min/h] Conversion factor: kcal/h to kW : 860 [(cal/h)/W] * Refer to the following for the
Q = qm x C x (T2 T1) x qv x C X T 1 x 35 x 4.186 x 103 x 3.0 60 = = 60 qm x C x (T2 T1) 860 Q = = 7325 [J/s] 7325 [W] = 7.3 [kW] x qv x 60 x C x T = Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 860 8.8 [kW] 1 x 35 x 60 x 1.0 x 103 x 3.0 860 = Thermo-chiller qv: Circulating fluid flow rate Q: Heat generation amount T2: Return temperature Users equipment 7325
A B C D A B C D Bore size (mm) Port aperture A 12 (1) (1) (1) 16 (2) (2) (2) B D 20 (2) (2) (2) View from piston rod end 25 (2) (2) (2) 32 C (2) 40 (2) 50 (2) Operating Range Auto Switch Mounting Bracket/Part No. (mm) Reed switch Solid state switch Applicable switch Auto switch model Bore size Bore size (mm) Mounting bracket part no.
.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com Leakage test result a t e l u g c Stainless steel linear guide & low particulate generation vacuum grease e i 2 t n r a e CX p r a 0.0 10 0 20 10 w 10-10 0 5 10 t i o o n L DTime [min] Operation cycles -X e e a a l l k k a t e l u w w g a a c 2 e i o
Note 3) A particulate generation test has been conducted in a vacuum environment of 10-Pa. a t e l u g c 2 Stainless steel linear guide & low particulate generation vacuum grease e i t n r a e p r a 0.0 10 0 20 10 w t i o o n L Operation cycles a t e l u g c e 1 i t n r a e Particulate generation from the linear guide unit has been reduced with the use of a stainless steel linear guide and
For critical applications use A at 2 PSI P . A 10 PSI P will save money and mounting space. Method 2: Chart Index Cv against Bore Size vs. Inches of stroke per second. Assuming 80 PSI and P = 80%.
For critical applications use A at 2 PSI P . A 10 PSI P will save money and mounting space. Method 2: Chart Index Cv against Bore Size vs. Inches of stroke per second. Assuming 80 PSI and P = 80%.
Used as IO-Link device 18 to 30 VDC, including ripple (p-p) 10% 1 Electric spec.
(Port indication: P: supply port; V: vacuum port; E: exhaust port.) Matching the ejector to the vacuum circuit Refer to technical data on page 13-110 to 19 for precautions on the vacuum circuit.