MHZ Gripping point L (mm) Gripping point L (mm) DMHZ2-40 MHZ2-16/11-MHZ2-16 200 2060 50 150 Overhang H (mm) Overhang H (mm) Pressure 0.2 MPa Pressure 0.2 MPa Pressure 0.2 MPa Pressure 0.2 MPa 40 0.3 MPa 0.3 MPa 100 0.3 MPa 0.4 MPa 0.5 MPa 0.6 MPa 0.7 MPa 0.3 MPa 30 0.4 MPa 0.4 MPa 0.4 MPa 0.5 MPa 0.5 MPa 0.5 MPa 0.6 MPa 0.6 MPa, 0.7 MPa 0.6 MPa, 0.7 MPa 20 0.7 MPa 50 10 0 50 100 150 200 0 10
Part No. 1 3 to 90 N X 8 31 TCU0425l -1-N-X6 L X 5.9 + 200 L X 5.2 + 200 1 3 to 90 N X 4 18 TCU0805l-1-N-X6 8 5 TCU0425l -2-N-X6 42 N X 8 L X 4.4 + 200 L X 3 + 200 2 3 to 90 N X 16 2 3 to 40 28 4 2.5 TCU0805l-2-N-X6 TCU0425l -3-N-X6 52 N X 12 3 3 to 63 L X 2.9 + 200 1 3 to 45 L X 5 + 200 N X 10 28 TCU1065l-1-N-X6 10 6.5 L X 5.3 + 200 L X 3 + 200 N X 6 24 1 3 to 90 52 2 3 to 35 N X 20 TCU0604l
How to Order Integrated Display Type M PF2A7 10 01 27 Flow rate range 1 to 10 l/min 5 to 50 l/min 10 to 100 l/min 20 to 200 l/min 50 to 500 l/min 10 50 11 21 51 Thread type Unit specification Nil M With unit switching function Fixed SI unit Note) Nil N F Lead wire (Refer to page 35.)
kPa Supply pressure 400 kPa Supply pressure 200 kPa Supply pressure 400 kPa 40 40 40 Pressure loss [kPa] Pressure loss [kPa] Pressure loss [kPa] Supply pressure 200 kPa Supply pressure 400 kPa 30 30 30 20 20 20 10 10 10 0 0 0 0 400 800 1200 1600 2000 0 100 200 300 400 500 0 200 400 600 800 1000 Flow [L/min] Flow [L/min] Flow [L/min] IN Side Straight Piping Length and Accuracy (Reference
L* N x 4 N x 8 N x 12 N x 6 N x 12 N x 18 N x 8 N x 16 N x 10 N x 20 N x 12 N x 24 D 18 28 28 24 37 37 31 42 52 52 67 67 TCU0425-1N-X6 TCU0425-2N-X6 TCU0425-3-N-X6 TCU0604-1-N-X6 TCU0604-2-N-X6 TCU0604-3-N-X6 TCU0805-1-N-X6 TCU0805-2-N-X6 TCU1065-1-N-X6 TCU1065-2-N-X6 TCU1208 -1-N-X6 TCU1208 -2-N-X6 LX5.9 + 200 LX4.4 + 200 LX2.9 + 200 LX5.3 + 200 LX3.8 + 200 LX2.5 + 200 LX5.2 + 200 LX3 +
IR 0.5 0.5 0.6 Set pressure (MPa) Set pressure (MPa) 0.4 Set point VEX 0.5 0.3 0.4 0.0 AMR 0.3 0.2 0.2 0.5 ITV 0.1 0.1 1.0 0.0 0.0 IC 0 50 100 200 150 0 50 100 150 200 250 0.8 0.2 0.4 0.6 Flow rate (/min (ANR)) Flow rate (/min (ANR)) Supply pressure (MPa) VBA VE Series ITV203 VY1 G Repeatability Linearity Hysteresis 1.0 0.6 1.0 PPA 0.5 Output deviation factor (%F.S.)
18 NPN/1 setting, three revolution adjustment, analog 19 NPN/1 setting, 200 0 adjustment, analog 55 PNP/1 setting, 200 0 adjustment N O Z Z L E D I A M E T E R A 0.7: With Vacuum Release Valve B 1.0: With Vacuum Release Valve L E A D W I R E Blank 0.6m 30 3m 50 5m D I M E N S I O N S S E E N E X T P A G E Courtesy of Steven Engineering, Inc. !
P When mounted on the manifold, the common exhaust discharges the pilot and main valve exhaust through a common exhaust port to enable simple exhausting. 700 B 600 Max.operating speed (mm/s) Piping length1m JIS Symbol B A 500 Piping length5m A D SY (Single) 400 R P SYJ C 300 SX How to order valve with built-in speed controller SYJ5l 5l--lll l--l 200 VK Port size VZ 100 Config.
(the value under the prescribed conditions) 0.8 0.7 0.6 Subsonic Critical pressure 0.5 0.4 0.45 0.45 Sonic 0.4 0.4 0.35 0.35 0.3 0.3 0.3 0.25 0.2 0.25 0.2 0.2 0.15 0.15 0.1 0.05 0.1 0.1 0.05 S = 0.54 VDW101 10 60 50 40 30 20 10 20 VDW 1.6 S = 1.2 125 100 75 50 S = 3.2 VDW202.3 350 300 250 200 150 100 50 S = 5.8 VDW203.2 600 500 400 300 200 100 S = 2.8 VDW302 300 250 200 150 100 50 VDW303
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 19.80000 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 14.73269 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, .00000 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 15.07024 lb
High speed or high load cylinder applications frequently require additional speed and flow control devices to control the stopping of the load. SMC's RHC series features a longer cushion design which is capable of stopping heavy or high speed loads while maintaining the simplicity of a standard air cushion cylinder. This enhanced cushion allows the kinetic distance, which results in the
High speed or high load cylinder applications frequently require additional speed and flow control devices to control the stopping of the load. SMC's RHC series features a longer cushion design which is capable of stopping heavy or high speed loads while maintaining the simplicity of a standard air cushion cylinder. This enhanced cushion allows the kinetic distance, which results in the
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 13.33796 lb
High speed or high load cylinder applications frequently require additional speed and flow control devices to control the stopping of the load. SMC's RHC series features a longer cushion design which is capable of stopping heavy or high speed loads while maintaining the simplicity of a standard air cushion cylinder. This enhanced cushion allows the kinetic distance, which results in the
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 15.10174 lb
This is a legacy product. Please contact us for the latest version.sales@ocaire.com, CYL, HIGH POWER, ACTUATOR, RHC ROUND BODY HIGH POWER, NE, 50MM RHC DBL ACT SW CAPABLE, 14.73269 lb
High speed or high load cylinder applications frequently require additional speed and flow control devices to control the stopping of the load. SMC's RHC series features a longer cushion design which is capable of stopping heavy or high speed loads while maintaining the simplicity of a standard air cushion cylinder. This enhanced cushion allows the kinetic distance, which results in the