Your search for CXS returned 21 result(s)
There were no hits with the full part number, but there were 27 hits in the keyword search.
There were no hits with the full part number, but there were 8 hits in the keyword search.
Product Information » New Products Search Results
Dual Rod Cylinder/Basic Type: Slide Bearing Series CXS Bore Size: 20mm, Thread: ø6-ø20 Bore: M Thread; ø25,ø32 Bore: Rc 1/8, Stroke: 10mm, Auto Switch: Y59B--Solid State, Gen. Purpose, 2 Wire, Horizontal, 0.5M, Lead Wire or Prewired Connector: L (3m), Number: S (1 pc.)
Bore Size: 20mm, Thread: ø6-ø20 Bore: M Thread; ø25,32ø Bore: Rc 1/8, Stroke: 10mm, Auto Switch: Y59B--Solid State, Gen. Purpose, 2 Wire, Horizontal, 0.5M, Lead Wire or Prewired Connector: 3m, Number: 1 pc., Thread Port: -
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, GUIDE, DUAL ROD, ACTUATOR, CXS GUIDED CYLINDER, HM, 20MM CXS SLIDE BEARING, 1.15742 lb, ModelStandard stroke (mm) 1015202530354045506070758090100CXSM200.400.420.440.460.480.4950.510.530.550.5850.620.640.660.700.74
Select the graph that corresponds to the imaginary stroke l. l k Imaginary stroke l = (Stroke) + k + l k: Distance between the center and the end of the plate 20 6 mm 25 32 8 mm (Example) When using CXSM20-10 and l = 10 mm: Imaginary stroke l = 10 + 6 + 10 = 26 Therefore, the graph used for your model selection should be the one for CXSM20-30. 8-28-15 15 Series CXS Vertical Mounting Graph
L k Imaginary stroke L' = (Stroke) + k + L k: Distance between the center and the end of the plate 20 6mm 25 32 8mm (Example) When using CXSM20-10 and L = 10mm: Imaginary stroke L' = 10 + 6 + 10 = 26 Therefore, the graph used for your model selection should be the one for CXSM20-30 ( , ). 61 Series CXS Vertical Mounting [based on maximum speed (V)] Graph V = up to 200mm/s 1 Graph V = up to
Bore size (mm) 10, 20, 30, 40, 50 10, 20, 30, 40, 50 10, 20, 30, 40, 50, 75, 100 Standard stroke 6 10, 15 20, 25, 32 Applicable Auto Switch/Refer to page 8-30-1 for further information on auto switches.
Select the graph that corresponds to the imaginary stroke l. l k Imaginary stroke l = (Stroke) + k + l k: Distance between the center and the end of the plate 20 6 mm 25 32 8 mm (Example) When using CXSM20-10 and l = 10 mm: Imaginary stroke l = 10 + 6 + 10 = 26 Therefore, the graph used for your model selection should be the one for CXSM20-30. 8-28-15 15 Series CXS Vertical Mounting Graph
Select the graph that corresponds to the imaginary stroke l. l k Imaginary stroke l = (Stroke) + k + l k: Distance between the center and the end of the plate 20 6 mm 25 32 8 mm (Example) When using CXSM20-10 and l = 10 mm: Imaginary stroke l = 10 + 6 + 10 = 26 Therefore, the graph used for your model selection should be the one for CXSM20-30. 8-28-15 15 Series CXS Vertical Mounting Graph
Minimum Stroke for Auto Switch Mounting [mm] Auto switch model Number of auto switches Bore size 12 (10 x 2) 16 (12 x 2) 20 (16 x 2) 25 (20 x 2) 32 (25 x 2) 40 (32 x 2) 50 (40 x 2) 63 (45 x 2) 80 (56 x 2) 100 (71 x 2) D-M9V 1 5 2 5 D-M9 1 51 5 2 101 10 D-M9W 1 52 2 102 10 D-M9WV D-M9AV 1 52 2 10 D-M9A 1 52 2 102 1 Confirm that it is possible to secure the min. bending radius of 10 mm of the
Model CYP15 CYP32 Series Throttle valve 10-AS2200-01-X214 Elbow type 10-AS1200-M5-X216 Metal body piping type 10-AS2000-01-X209 In-line type 10-AS1000-M5-X214 10-AS2201F-01-04-X214 10-AS1201F-M5-04-X214 Elbow type (throttle valve) 10-AS2201F-01-06-X214 10-AS1201F-M5-06-X214 10-AS2201F-01-06-X214 Operation 10-AS2301F-01-04-X214 10-AS1301F-M5-04-X214 Resin body with One-touch fitting Caution
32 6 36.5 41.5 10 44 54 8.5 13.5 16 5,10 16 8 5.4 35.5 40.5 5, 10 38 8 39 44 10.5 46 56 9.5 14.5 20 5, 10 20 10 7 36.5 41.5 5, 10 47 7 41 46 11 47.5 57.5 10 15 25 5, 10 25 12 10 37.5 42.5 5, 10 52 12 42.5 47.5 10.5 50 50 12 17 32 5, 10 32 16 13.3 38 43 5, 10 45 13 45 50 11 56.5 66.5 12 17 40 5, 10 40 16 18.3 44.5 41.5 5, 10 52 13 51.5 56.5 10.5 68.5 88.5 18 28 50 10, 20 50 20 17.6 50.5 60.5
32 6 36.5 41.5 10 44 54 8.5 13.5 16 5,10 16 8 5.4 35.5 40.5 5, 10 38 8 39 44 10.5 46 56 9.5 14.5 20 5, 10 20 10 7 36.5 41.5 5, 10 47 7 41 46 11 47.5 57.5 10 15 25 5, 10 25 12 10 37.5 42.5 5, 10 52 12 42.5 47.5 10.5 50 50 12 17 32 5, 10 32 16 13.3 38 43 5, 10 45 13 45 50 11 56.5 66.5 12 17 40 5, 10 40 16 18.3 44.5 41.5 5, 10 52 13 51.5 56.5 10.5 68.5 88.5 18 28 50 10, 20 50 20 17.6 50.5 60.5
A part z1 m1 = 20 x 3 x 4 x 2.7 x 10-6 = 6.48 x 10-4 (kg) Weight calculation m1 = a x b x c x Relative density IZ1 Inertial moment around Z1 axis IZ1 = {m1 (a2 + b2) / 12} x 10-6 = {6.48 x 10-4 x (202 + 32)/12} x 10-6 = 2.21 x 10-8 (kg.m2) = 2.21 x 10-8 + 6.48 x 10-4 x 16.42 x 10-6 = 0.20 x 10-6 (kg.m2) IA Inertial moment around Z axis IA =IZ1 + m1r12 x 10-6 z f2 z2 B part r2 = 23.5(mm)
Load weight (kg) Load weight (kg) Load weight (kg) 10 10 10 MY1H40 MY1H40 MY1H40 MY1H40 MY1H40 MY1H40 MY1H40 2. Reference formula [Dynamic moment at impact] Use the following formulae to calculate dynamic moment when taking stopper impact into consideration.