Me3 Guide central axis We W L2 A Me1 Me1 = 1/3WeL1 = 1/31680.05 = 2.8 [Nm] 4 = Me1/Me1max = 2.8/7.2 = 0.389 W We Investigate Me1.
Dynamic moment Va Calculation Example m Operating conditions Cylinder: CYV32 Mounting: Horizontal wall mounting Maximum speed: U = 300 [mm/s] Load mass: m = 1 [kg] (excluding mass of the arm section) L1 = 50 [mm] L2 = 50 [mm] L2 L1 Item Load factor n Note 1. Maximum load mass m 1 = m/m max = 1/5 = 0.20 L2 Review m. L1 2.
Orange Calculation of Connected Plug and Socket Dimension Overall length of connected plug and socket B = Plug (L1 L2) + Socket (L2) + 0.5 Plug Socket Example) Overall length of KK3P-01MS (plug) and KK3S-01MS (socket) when they are connected.
Cylinder: MXY8-100 Cushion: Rubber stopper Mounting: Horizontal wall mounting Average speed: Va = 300 [mm/s] Load weight: W = 0.2 [kg] L2 = 40 mm L3 = 50 mm Model to be used Type of cushion Mounting orientation Average speed Va (mm/s) Load weight W (kg) Overhang Ln (mm) W L3 + A3 L2 Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650
Dynamic moment Va Calculation example m Operating conditions Cylinder: CYP32 Mounting: Horizontal wall mounting Maximum speed: U = 300 [mm/s] Load mass: m = 1 [kg] (excluding mass of arm section) L1 = 50 [mm] L2 = 50 [mm] L2 L1 Item Load factor n Note 1. Maximum load mass m 1 = m/mmax = 1/5 = 0.20 L2 Review m. L1 M2 = m g (L1 + B) 103 2.
Dynamic moment Va Calculation example m Operating conditions Cylinder: CYP32 Mounting: Horizontal wall mounting Maximum speed: U = 300 [mm/s] Load mass: m = 1 [kg] (excluding mass of arm section) L1 = 50 [mm] L2 = 50 [mm] L2 L1 Item Load factor n Note 1. Maximum load mass m 1 = m/mmax = 1/5 = 0.20 L2 Review m. L1 2.
Dynamic moment Va Calculation example m Operating conditions Cylinder: CYP32 Mounting: Horizontal wall mounting Maximum speed: U = 300 [mm/s] Load mass: m = 1 [kg] (excluding mass of arm section) L1 = 50 [mm] L2 = 50 [mm] L2 L1 Item Load factor n Note 1. Maximum load mass m 1 = m/mmax = 1/5 = 0.20 L2 Review m. L1 2.
307 394 481 568 655 742 829 916 1003 L2 = 87 x n + 133 Model 2 257 3 344 4 431 5 518 6 605 7 692 8 779 9 866 10 953 L L1 VVPA450 L3 L4 356 464 572 680 788 896 1004 L4 = 108 x n + 140 L3 = 108 x n + 90 306 414 522 630 738 846 954 VVPA460 ( ) for VVPA460 5-3-30 1 4/5 Port Air Operated Valve Series VSA420 Model Flow characteristics P A/B A/B EA/EB Valve model Port size Rc Note) Weight
L2 A4 K = 0.6 W Mey Mep Note) No need to consider this load factor in the case of using perpendicularly in a vertical position.
Cylinder: MXJ6-10 Cushion: Rubber stopper Mounting: Horizontal wall mounting Average speed: Va = 100 mm/s Load mass: W = 0.1 kg L2 = 40 mm L3 = 50 mm Model to be used Type of cushion Mounting orientation Average speed Va (mm/s) Load mass W (kg) Overhang (mm) MXU MXS L2 MXQ L3+A3 MXF Load Mass 2 MXW V = 1.4 Va Correction factor (Reference value) V = 1.4 x 100 = 140 Find the collision
385 VV2CS3 L2 89 127.5 166 204.5 243 281.5 320 358.5 397 L3 101 139.5 178 216.5 255 293.5 332 370.5 409 L1 83 124.5 166 207.5 249 290.5 332 373.5 415 VV2CS4 L2 95 136.5 178 219.5 261 302.5 344 385.5 427 L3 107 148.5 190 231.5 273 314.5 356 397.5 439 Manifold composition Note) Manifold base is consisted of the junction of 2 and 3 station bases. 2 stns. x 1 3 stns. x 1 2 stns. x 2 2 stns.
L2 89 358.5 139.5 216.5 332 178 255 409 293.5 L3 101 370.5 124.5 207.5 332 166 249 415 290.5 L1 83 373.5 VV2CS4 136.5 219.5 344 178 261 427 302.5 L2 95 385.5 148.5 231.5 356 190 273 439 314.5 L3 107 397.5 Manifold composition 3 stns. x 1 2 stns. + 3 stns. 2 stns. + 3 stns. x 2 2 stns. x 2 3 stns. x 2 2 stns. x 2 + 3 stns. x 2 2 stns. x 2 + 3 stns. 2 stns. x 1 3 stns. x 3 Note) Manifold bases
San=a1+a2+a31 3.11-10 Air Slide Table Series MXS Allowable load: W (N) Fig.1 Overhang: Ln (mm), Correction value for moment center distance An (mm) Fig.2 Pitch moment Yaw moment Roll moment W My Mp Mr W W W Static moment Dynamic moment L1 A1 L3 A5 L2 A3 CL W Mp Mr My W W MLGC L3 A6 W L1 A2 L2 A4 CNA W Mey Mep CB L2 A4 CV/MVG A2 L3 Work mounting coefficient: K Fig.3 CXW Table mounting CXS
A3 End plate mounting MX Mp Mr W My W W MTS W L3 A6 W L1 A2 L2 A4 MY K = 0.6 W Mey Mep CY L2 A4 MG Note) No need to consider this load factor in the case of using perpendicularly in a vertical position.
L Dimension L1 = 31n + 29, L2 = 31n + 14 n: Station 2 91 76 3 122 107 4 153 138 5 184 169 6 215 200 7 246 231 8 277 262 n Symbol L1 L2 853 VEX13 Series 0 3 Precautions Be sure to read this before handling the products. Refer to back page 50 for Safety Instructions and pages 387 to 391 for Precautions on every series. Operating Fluid Caution 1.
Dynamic moment MG Va Calculation Example CX m Operating Conditions Cylinder: CYP32 Mounting: Horizontal wall mounting Maximum speed: U = 300 [mm/s] Load mass: m = 1 [kg] (excluding mass of arm section) L1 = 50 [mm] L2 = 50 [mm] D-X L2 L1 20Data Item Load factor n Note 1. Maximum load mass m 1 = m/mmax = 1/5 = 0.20 L2 Review m. L1 M2 = m g (L1 + B) 103 2.
Cylinder: MXY8-100 Cushion: Rubber stopper Mounting: Horizontal wall mounting Average speed: Va = 300 [mm/s] Load mass: W = 0.2 [kg] L2 = 40 mm L3 = 50 mm Model to be used Type of cushion Mounting orientation Average speed Va (mm/s) Load mass W (kg) Overhang Ln (mm) W L3 + A3 L2 Load Mass 2 V = 1.4 Va V = 1.4 x 300 = 420 Correction factor (Reference value) Find the collision speed
L1 L2+A5 L3 Kinetic Energy 2 Find the kinetic energy E (J) of the load. Find the allowable kinetic energy Ea (J).
A3 MXH W Mp Mr W MXU W My L3 A6 W L1 A2 L2 A4 MXS W Mey Mep MXQ Note) There is no need to consider this load factor in the case of using perpendicularly in a vertical position.
IDF22E-20, IDF37E-20 IDF22E-30, IDF37E-30, IDF55E-30, (Single phase AC200V) IDF75E-30 (3 phase AC200V) L N PE L1 L2 L3 PE Customer Connection Side Customer Connection Side Terminal Connecting Screw: M3 Terminal Connecting Screw: M3 Applied Pressure Terminal: 1.25-3 Applied Pressure Terminal: 1.25-3 (Width 6.5mm and below) (Width 6.5mm and below) IDF Series 1-1 Parts Name and Functions