Series CQS Compact Cylinder Compact Type ø12, ø16, ø20, ø25 Allowable Kinetic Energy 12 16 20 25 Bore size (mm) lbf-ft J J J lbf-ft J lbf-ft lbf-ft 0.066 0.090 0.055 0.022 0.028 0.038 0.016 Standard 0.041 0.133 0.180 0.110 0.043 0.055 0.075 0.032 With rubber bumper 0.081 Minimum Operating Pressure 20/25 12/16 Bore size (mm) MPa psi MPa psi Min. operating pressure 0.05 7.3 0.07 10.2 2 Compact Cylinder Series CQS OUT IN Double Acting Single or Double
Av = Q (8) P Av : Flow coefficient [m2] Q : Flow rate [m3/s] P : Pressure difference [Pa] : Density of fluid [kg/m3] (3) Formula of flow rate It is described by the known unit. Also, the flow characteristics line shown in the Graph (2).
Note Power supply/Output connection cable Description ZS-28-A D Mounting screw (M3 x 8L) (Accessory) Bracket ZS-28-B With M3 x 5L (2 pcs.) Sensor connector ZS-28-C 1 pc. Panel mount adapter Panel mount adapter ZS-27-C With M3 x 8L (2 pcs.) ZS-27-D With M3 x 8L (2 pcs.)
45 L 15 50 CQ-M3 x 50 L 20 55 CQ-M3 x 55 L 25 60 CQ-M3 x 60 L 30 65 CQ-M3 x 65 L 35 70 CQ-M3 x 70 L 40 75 CQ-M3 x 75 L 45 80 CQ-M3 x 80 L 50 85 CQ-M3 x 85 L 20 5.5 D C 5 45 CQ-M3 x 45 L 10 50 CQ-M3 x 50 L 15 55 CQ-M3 x 55 L 20 60 CQ-M3 x 60 L 25 65 CQ-M3 x 65 L 30 70 CQ-M3 x 70 L 35 75 CQ-M3 x 75 L 40 80 CQ-M3 x 80 L 45 85 CQ-M3 x 85 L 50 90 CQ-M3 x 90 L 25 8 6 MXZ Series Dimensions: MXZ12
Moment (Nm) Moment (Nm) Moment (Nm) Load mass (kg) M1 = F1 x L1 Piston speed V (mm/s) ML1C/M2, M3 M2 = F2 x L2 M3 = F3 x L3 Piston speed V (mm/s) (How to calculate the load ratio) A. Consider (1) max. load mass, (2) static moment, (3) dynamic moment (when stopper collides) when calculating the max. allowable moment and load mass.
Heat generation amount by users equipment Q : Unknown [W] ([J/s]) Circulating fluid : Tap water* Example of current measurement units (Reference) Circulating fluid mass flow rate qm : (= x qv 60) [kg/s] Circulating fluid density : 1 [kg/L] Circulating fluid (volume) flow rate qv : 35 [L/min] Circulating fluid specific heat C : 4.186 x 103 [J/(kgK)] Circulating fluid outlet temperature
Heat generation amount by users equipment Q : Unknown [W] ([J/s]) Circulating fluid : Tap water* Example of current measurement units (Reference) Circulating fluid mass flow rate qm : (= x qv 60) [kg/s] Circulating fluid density : 1 [kg/L] Circulating fluid (volume) flow rate qv : 70 [L/min] Circulating fluid specific heat C : 4.186 x 103 [J/(kgK)] Circulating fluid outlet temperature
Application example Transferring Cutting 1 Series CY3B/CY3R Model Selection Method Operating conditions E: Kinetic energy of load (J) (W + WB) V 2 E = x ( ) 2 1000 Es: Allowable kinetic energy for intermediate stop using an air pressure circuit (J) Fn: Allowable driving force (N) MD: Maximum allowable moment (Nm) when a connection bracket, etc. is carried directly Ps: Operating pressure limit
Application example Transferring Cutting 1 Series CY3B/CY3R Model Selection Method Operating conditions E: Kinetic energy of load (J) (W + WB) V 2 E = x ( ) 2 1000 Es: Allowable kinetic energy for intermediate stop using an air pressure circuit (J) Fn: Allowable driving force (N) MD: Maximum allowable moment (Nm) when a connection bracket, etc. is carried directly Ps: Operating pressure
Heat generation amount by users equipment Q : Unknown [W] ([J/s]) Circulating uid : Tap water Example of conventional measurement units (Reference) Circulating uid mass ow rate qm : (= x qv 60) [kg/s] Circulating uid density : 1 [kg/L] Circulating uid (volume) ow rate qv : 35 [L/min] Circulating uid specic heat C : 4.186 x 103 [J/(kgK)] Circulating uid outlet temperature T1 : 293 [K] (
Bore 6 10 16 6.4 8.1 9.2 5.5 7 8 2.4 3.2 4 M3 X 0.5 NTJ-006A M4 X 0.7 NTJ-010A Clevis pins and set rings are attached.
M3 x 0.5 x 3L M8 x 1.25 x 8L (Bolt holder) (Hexagon socket head set screw) 31 0.5 45 45 3 3 5.3 5.3 250.2 250.2 16 32 2-M3 x 0.5 through 6.5 counter bore depth 5 (Same on the opposite side) 3.4 through 3 3 45 45 5.5 M2.5 x 0.45 x 6L (Cap screw) M3 x 0.5 x 12.5L (Hexagon bolt) and M3 x 0.5 (Hexagon nut) 2-M3 x 0.5 through Steel ball Plug 2-M3 x 0.5 through 2.75 (11) (10+ST) 250.2 4 Part no
Lock ring Lock ring Retraction locking Extension locking 1) Remove the dust cover. 2) Screw a manual unlocking bolt (a bolt of M3 x 0.5 x 15l or more on the market) into the lock ring threads as shown above, and lightly push the bolt in the direction of the arrow (rear side) to unlock. 1) Remove the dust cover. 2) Screw a manual unlocking bolt (a bolt of M3 x 0.5 x 15l or more on the market
7 7.8 17 22.5 24 14.5 0.8 5 3.2 M3x0.5 KJH23-M3 7 18 15.5 14.5 0.9 1.6 3.2 M5x0.8 KJW23-M5 7 7.8 17 25 26 14.5 2.6/2.2 6.3 3.2 M5x0.8 KJH23-M5 7 18.5 15.5 14.5 3/2.5 2.1 3.2 R(PT)1/8 KJW23-01S 10 7.8 17 25 25 14.5 2.6/2.2 10.4 3.2 R(PT)1/8 KJH23-01S 10 16.5 12.5 14.5 3/2.5 5 4 M3x0.5 KJW04-M3 7 8.9 17.5 23 25 14.5 0.8 5 4 M3x0.5 KJH04-M3 8 18 15.5 14.5 0.9 1.9 4 M5x0.8 KJW04-M5 7 8.9 17.5
Max. air flow rate (m3/min (ANR)) JIS Symbol P . 14-20-55 Inlet pressure (MPa) Caution Be sure to read before handling.
Nm N M1 M M3 W W2 W W4 ML2B25 10.0 1.2 3.0 200.0 58.0 65.0 100.0 ML2B32 20.0 2.4 6.0 300.0 80.0 96.0 150.0 ML2B40 40.0 4.8 12.0 500.0 106.0 140.0 250.0 ML2B25 ML2B32 ML2B40 J 0.43 0.68 1.21 18 ML2B/M1 ML2B/W1 ML2B/W1 0 0 0 Nm 0 0 0 N N 0 m/s m/s m/s ML2B/M2 ML2B/W2 ML2B/W2 N m N N m/s ML2B/M3 m/s m/s 20 ML2B/W3 ML2B/W3 10 Nm 5 3 2 1 N N m/s m/s m/s ML2B/W4 500 N 00 N
Compressed air 1.0MPa Fluid Max. operating pressure Min. operating pressure (1) 0.05MPa 1.5MPa Proof pressure Ambient and fluid temperature Filtration rating 5 to 60C 0.01m(95% particle size collection) Oil mist removal rate Max.0.1mg/m3 (ANR) (2) (At saturation of element oil, less than 0.01mg/m3(ANR){0.008ppm}) 2 years or when pressure drop reaches 0.1MPa Element life Note 1) With N.O.auto
Calculate (1) (Wmax) from the graph of max. payload (W1, W2, W3) and calculate (2) and (3) (Mmax) from the maximum allowable moment graph (M1, M2, M3).
Cool from 30C (303 K) to 20C (293 K). : Tap water Density g: 1 x 103 kg/m3 Specific heat C: 4.2 x 103 J/(kgK) Water bath * Refer to the information shown below for the typical physical property values by circulating fluid.
Calculate (1) (Wmax) from the graph of max. payload (W1, W2, W3) and calculate (2) and (3) (Mmax) from the maximum allowable moment graph (M1, M2, M3).