17

m2 M3 m3 1.

SY

ARBY3000-05--2 (for mounting on odd number stations) ARBY3000-06--2 (for mounting on even number stations) ARBY3000-M1--2 ARBY5000-00--2 ARBY5000-M1--2 + + + + + Accessories Caution Series Round head combination screw Gasket Mounting screw tightening torques ARBY3000 SY3000-23-10 (M2 x 36) SX3000-57-4 M2: 0.15Nm M3: 0.6Nm M3 x 48.5 (Flat nickel plated) ARBY5000 SX5000-57-5 91 Base Mounted

SX

Description Note M2: 0.17 Nm M3: 0.8 Nm M4: 1.4 Nm 1 4 3 8 SY5000-27-1 Rc: SY7000-27-1 Rc: SY7000-27-2 SY3000-27-1 Sub-plate Aluminum die-casted i Gasket o HNBR SY5000-11-15 SY7000-11-11 SY3000-11-25 Round head combination screw For valve mounting (Matt nickel plated) M3 x 30 M4 x 35 SX3000-22-2 (M2 x 24) 1-6-31 Base Mounted 32 Series SX3000/5000/7000 Dimensions: Series SX3000 2 position

This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, .00000 lb

This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, .00000 lb

This is a legacy product. Please contact us for the latest version.sales@ocaire.com, VACUUM EJECTOR, COMPACT, VACUUM SERIES, ZA COMPACT VACUUM EJECTOR, AG, ZA NOZZLE SIZE 0.5, .23148 lb

Direct Operated 2 Port Solenoid Valve For Water, Oil, Steam, Air Series VX21/22/23 1

Max. operating pressure differential (MPa) Weight (g) Max. operating pressure differential (MPa) Weight (g) Flow characteristics Flow characteristics Max. system Note) Max. system Note) Orifice Orifice size (mm) Model AC DC Port size Port size (mm) Model AC DC pressure pressure size (MPa) Av x 10-6 m2 Cv converted (MPa) Av x 10-6 m2 Cv converted 2 VX2110-01 VX2120-01 VX2130-01 VX2110-02 VX2120

Slider Type/Ball Bushing Bearing

L2 L1 xStatic moment Examine M2. Since M1 & M3 are not generated, investigation is unnecessary. M2 = W L1 = 10 0.05 = 0.5 [Nm] 2 = M2/M2 max = 0.5/16 = 0.031 W = 1 [kg] = 10 [N] W M Find the value M2 max when Va = 300 mm/s from Graph (3).

Clean Room Rodless Cylinder Series CYP ø15, ø32 1

L1 M2 = m g (L1 + B) 103 2. Static moment m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.

Rodless Cylinder for Vacuum Series CYV ø15, ø32 1

Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.

CYV

Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.

CYP

L1 M2 = m g (L1 + B) 103 2. Static moment m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.

CYPSeries

Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.

CYPSeries

Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 & M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103 m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We (L2 + A) 103 3.

Rodless Cylinder for Vacuum Series CYV ø15, ø32

Static moment M2 = m g (L1 + B) 103 m x g = 1 9.8 (50 + 48) 103 Review M2. Since M1 and M3 are not generated, review is unnecessary. = 0.96 [Nm] 2 = M2/M2 max = 0.96/4 = 0.24 M Guide shaft mounting surface L1 B We = 5 x 103m g U = 5 x 103 1 9.8 300 = 14.7 [N] Me3 = 1/3 We(L2 + A) 103 3.

Precision Air Slide Table Series MXP ø6, ø10, ø12, ø16, (ø8: new addition, see 8-8-23 ) 1

Dimensions 2-M2 x 3 (Countersunk head Phillips screw for precision instruments) 2-M2 x 3 (Cross recessed head machine screw for precision instruments) 2-M3 x 8 (Bolt with hex. hole) 2-M2 x 5 (Bolt with hex. hole) MXP10/12/16 MXP6 Applicable size Switch rail part no.

MHC2

MHCM2-7S D8.3 205.2 2-M2 x 0.4 thread (Mounting thread) 2-M2 x 0.4 depth 4 (Mounting thread) 2.5 2 1.5 When open 20 When closed 7 10 6 4.5 15 11 7.7 1.8 16.5 6 100.05 (23) M3 x 0.5 (Finger closing port) 2-M2 x 0.4 thread (Attachment mounting thread) 4 0 0.03 3 12-8-23

CY1

Static moment M2 = WL1 = 100.05 = 0.5 [Nm] 2 = M2/M2max = 0.5/16 = 0.031 W = 1 [kg] =10 [N] Investigate M2. Since M1 & M3 are not generated, investigation is unnecessary. Find the value of M2max when Va = 300mm/s from . W M L1 From V = 1.4Va We = WV = 4/100101.4300 = 168 [N] Me3 = 1/3We(L2-A) = 1/31680.032 = 1.8 [Nm] 3 = Me3/Me3max = 1.8/7.2 = 0.250 3.

MHC2

MHCM2-7S D8.3 205.2 2-M2 x 0.4 thread (Mounting thread) 2-M2 x 0.4 depth 4 (Mounting thread) 2.5 2 1.5 When open 20 When closed 7 10 6 4.5 15 11 7.7 1.8 16.5 6 100.05 (23) M3 x 0.5 (Finger closing port) 2-M2 x 0.4 thread (Attachment mounting thread) 4 0 0.03 3 12-8-23

Angular Air Gripper Series MHC2/MHCA2/MHCM2

= d x e x f x Relative density m2 = 4 x 5 + 6 x 2.7 x 10-6 = 3.24 x 10-4 (kg) Inertial moment around Z2 axis IZ2 = {m2 (d2 x e2) / 12} x 10-6 IZ2 = {3.24 x 10-4 x (42 + 52) / 12} x 10-6 = 1.11 x 10-9 (kg.m2) = 1.11 x 10-9 + 3.24 x 10-4 x 23.52 x 10-6 = 0.18 x 10-6 (kg.m2) Inertial moment around Z axis IB = IZ2 x m2r22 x 10-6 IB Thus, the total inertial moment is I = IA x B I = 0.20 x 10