Mechanically Jointed Rodless Cylinder Series MY3 ø16, ø25, ø40, ø63 1 a piston speed that will not exceed the absorption capacity of the air cushion and stroke adjusting unit. 80 10 70 45 25 1.96 8.83 4.22 6.86 8.34 Extended Spring force (N) 4.22 20.01 6.86 15.98 20.50 Compressed Operating temperature range (C) Standard Stroke 5 to 60 Bore size (mm) Max. manufacturable stroke (mm) Standard stroke (mm) Weight Unit: kg 100, 200, 300, 400, 500, 600 700, 800, 900
When air is supplied from the unlocking port, y the piston for locking ascends and releases the lock. 3 Centering Unit MACM Series How to Order X114 4 P 20 MACM Centering unit Made to order (Table material) X114 Stainless steel Ultra high molecular weight polyethylene Cast nylon X115 X116 Allowable load weight Symbol Allowable load weight 2 450 lbf [2 KN] 4 900 lbf [4 KN] 6 1350 lbf [6 KN
Refer to the cylinder catalog for details. 11 Optimum Actuation Size Chart of Air Cylinder For JSY5000, A, B port: 12 EX120 EX260 EX250 EX600 EX245 Chart Valve Lead Wire D-sub Flat Ribbon Terminal Block Connector Connecting Base Horizontal Vertical (Upward) Average speed [mm/s] 0 100 200 300 400 500 600 700 800 900 1000 50 63 Plug-in Common Dimensions Made to Order Manifold Exploded View
12 19 25 3/16" 1/8" 1/4" 3/8" 1/2" 3/4" 1" 2 3 Union elbow reducing LQ1E-R LVC 4 5 LVA P.889 6 LVH 2 LVD 3 Union tee reducing LQ1T-R 4 LVQ 5 LVP P.891 6 2 LVW 3 Panel mount union reducing LQ1P-R LQ1 LQ1 4 LQ3 5 P.896 6 LVN 2 LQHB 3 Union reducing LQ1U-R TL TIL 4 5 TLM TILM P.897 6 TD TID 2 TH TIH 3 Space saving union elbow LQ1E-SS 4 5 SMC P.898 6 2 3 Space saving union tee LQ1T-S 4 5 P.900
Water Cooled substance mass m : (= x V) [kg] Cooled substance density : 1 [kg/L] Cooled substance total volume V : 250 [L] Cooled substance specific heat C : 4.186 x 103 [J/(kgK)] Cooled substance temperature when cooling begins T0 : 305 [K] (32 [C]) Cooled substance temperature after t hour Tt : 293 [K] (20 [C]) Cooling temperature difference iT : 12 [K] (= T0 Tt) Cooling time it : 900
Water Cooled substance mass m : (= x V) [kg] Cooled substance density : 1 [kg/L] Cooled substance total volume V : 150 [L] Cooled substance specific heat C : 4.186 x 103 [J/(kgK)] Cooled substance temperature when cooling begins T0 : 303 [K] (30 [C]) Cooled substance temperature after t hour Tt : 293 [K] (20 [C]) Cooling temperature difference iT : 10 [K] (= T0 Tt) Cooling time it : 900
Q = m x C x (T0 Tt) it = r x V x C x iT it = 1 x 20 x 4.2 x 103 x 12 900 = 1120 [J/s] 1120 [W] Q = m x C x (T0 Tt) it x 860 = c x V x 60 x C x iT it x 860 Cooling capacity = Considering a safety factor of 20%, 1120 [W] x 1.2 = 1344 [W] = 1 x 20 x 60 x 1.0 x 103 x 12 15 x 860 1120 [W] Thermo-chiller Q x t: Heat capacity [kJ] 20C Water bath Cooling capacity = Considering a safety factor
HRZ x V x C x iT it m x C x (T0 Tt) it Q = = HRZD 1 x 150 x 4.186 x 103 x 10 900 = = 6977 [J/s] 7.0 [kW] m x C x (T0 Tt) it x 860 x V x 60 x C x iT it x 860 HRW Q = = Cooling capacity = Considering a safety factor of 20%, 7.0 [kW] x 1.2 = HECR 1 x 150 x 60 x 1.0 x 103 x 10 15 x 860 8.4 [kW] = HEC Q x t: Heat capacity [kJ] Thermo-chiller Water bath 6977 [W] = 7.0 [kW] 20C HEB Cooling
Water Cooled substance mass m : (= x V) [kg] Cooled substance density : 1 [kg/L] Cooled substance total volume V : 150 [L] Cooled substance specific heat C : 4.186 x 103 [J/(kgK)] Cooled substance temperature when cooling begins T0 : 303 [K] (30 [C]) Cooled substance temperature after t hour Tt : 293 [K] (20 [C]) Cooling temperature difference iT : 10 [K] (= T0 Tt) Cooling time it : 900
Water Cooled substance mass m : (= x V) [kg] Cooled substance density : 1 [kg/L] Cooled substance total volume V : 300 [L] Cooled substance specific heat C : 4.186 x 103 [J/(kgK)] Cooled substance temperature when cooling begins T0 : 305 [K] (32 [C]) Cooled substance temperature after t hour Tt : 293 [K] (20 [C]) Cooling temperature difference iT : 12 [K] (= T0 Tt) Cooling time it : 900
Water Cooled substance mass m : (= x V) [kg] Cooled substance density : 1 [kg/L] Cooled substance total volume V : 150 [L] Cooled substance specific heat C : 4.186 x 103 [J/(kgK)] Cooled substance temperature when cooling begins T0 : 303 [K] (30 [C]) Cooled substance temperature after t hour Tt : 293 [K] (20 [C]) Cooling temperature difference iT : 10 [K] (= T0 Tt) Cooling time it : 900
Large Flow Air Filter AF800/900 Series AC-A Standard Specifications AF-A AF900 AF800 Model AF-A 1 4 1 2 Port size 1 2 1 AR-A Proof pressure 1.5 MPa Maximum operating pressure 1.0 MPa AL-A 5 to 60C (No freezing) Ambient and fluid temperature Standard specifications: 5 m Option: 2, 10, 20, 40, 70, 100 m Polycarbonate Filtration Bowl material AW-A Bowl capacity (cm3) 45 cm3 AC-B Weight (kg)
2.12 (53.8) AP1200HF 150 psig (1.0 MPa) 50 psig (0.35 MPa) Inlet pressure: 100 psig (0.69 MPa) Max. 6.5 (165.1) (When selecting the option code FC) Max. 5.6 (142.2) (When selecting the option code SC) 120 0.83 100 0.69 Delivery pressure (MPa) Delivery pressure (psig) Max. 6.0 (152.4) 1.5 (38.1) 80 0.55 60 0.41 2.62 (66.5) 40 0.28 20 0.14 0 0.00 0.69 (17.5) 0 100 200 300 400 500 600 700 800 900
Thomas Oil-less WOB-L Piston Compressor / Vacuum Pump Flow Rate: 3.38 CFM / 95.8 LPM , 3.38 CFM / 95.8 LPM, Max Vacuum: 26.6 in HgV / -900 mbar , 26.6 in HgV / -900 mbar, Features & Benefits: Plug-and-play easy to use BLDC technology 24VDC and 48VDC motor options Onboard integrated brushless DC (BLDC) motor controller Seven convenient fixed speed output
Thomas Oil-less WOB-L Piston Compressor / Vacuum Pump Flow Rate: 3.38 CFM / 95.8 LPM , 3.38 CFM / 95.8 LPM, Max Pressure: 60 PSIG / 4.1 bar , 60 PSIG / 4.1 bar, Max Vacuum: 26.6 in HgV / -900 mbar , 26.6 in HgV / -900 mbar, Features & Benefits: Plug-and-play easy to use BLDC technology 24VDC and 48VDC motor options Onboard integrated brushless DC
The CLS series cylinder with lock is ideal for applications requiring intermediate and emergency stop and drop prevention. The compact lock unit is lightweight and saves space. A switch is optional on the brake cylinder so the operating state of the lock unit (brake piston) can be detected using the switch signal. By separating the lock mechanism and the brake cylinder, SMC has minimized
The CLS series cylinder with lock is ideal for applications requiring intermediate and emergency stop and drop prevention. The compact lock unit is lightweight and saves space. A switch is optional on the brake cylinder so the operating state of the lock unit (brake piston) can be detected using the switch signal. By separating the lock mechanism and the brake cylinder, SMC has minimized
The CLS series cylinder with lock is ideal for applications requiring intermediate and emergency stop and drop prevention. The compact lock unit is lightweight and saves space. A switch is optional on the brake cylinder so the operating state of the lock unit (brake piston) can be detected using the switch signal. By separating the lock mechanism and the brake cylinder, SMC has minimized
The CLS series cylinder with lock is ideal for applications requiring intermediate and emergency stop and drop prevention. The compact lock unit is lightweight and saves space. A switch is optional on the brake cylinder so the operating state of the lock unit (brake piston) can be detected using the switch signal. By separating the lock mechanism and the brake cylinder, SMC has minimized
resistance [m/s2] Note 3)Actuation typeGuide typeOperating temperature range [nC]Operating humidity range [%RH]Motor sizeMotor output [W]Motor typeEncoderRated voltage [V]Power consumption [W] Note 4)Standby power consumption when operating [W] Note 5)Max. instantaneous power consumption [W] Note 6)Type Note 7)Holding force [N]Power consumption [W] Note 8)HorizontalLEFB16A300, 500, 600, 700800, 900