Electric Actuator High Rigidity and High Precision Slider Type Circular arc grooves allow for high rigidity and high precision. Moment resistance*1 *2 61% Improved by up to Table displacement*1 50% Reduced by up to With internal battery-less absolute e Calculation example) T1 to T4 can be calculated as follows. L Speed: V [mm/s] a1 a2 T1 = V/a1 = 300/3000 = 0.1 [s], T3 = V/a2 = 300/3000 = 0.1 [s] Time T = T1 + T2 + T3 + T4 [s] [s] L 0.5 V (T1 + T3) V T1: Acceleration time and T3: Deceleration time can be found by the following equation.
L Speed: V [mm/s] Cycle time T can be found from the following equation. a1 a2 T = T1 + T2 + T3 + T4 [s] T1: Acceleration time and T3: Deceleration time can be obtained by the following equation. Time [s] T1 = V/a1 [s] T3 = V/a2 [s] T1 T2 T3 T4 T2: Constant speed time can be found from the following equation.
STATION No (X10) 161 (x10) STATION No (X1) (x1) B RATE IF CC-Link F D C 10Mbps B 5Mbps A 2.5Mbps 230.4kbps 9 625kbps 8 156kbps 7 5 4 10Mbps 3 5Mbps 2 2.5Mbps 115.2kbps 1 625kbps 0 156kbps B RATE 1(LEC-T1)IF 115.2kbps 2 15 - 4.2 (CN2SW) CC-Link (CN2SW)CC-Link (CN2SW) () PC/TB (CN2)(LEC-T1-)(LEC-W2)(LEC) (CN2SW)CC-Link (LEC) 16 - 4.3 (LEC) (LEC)(LEC-T1-) (LEC-W2)(LEC) (LEC)(LEC)(
)IF115.2kbps 2 4.2(CN2SW) TM (CN2SW) Deviceet TM(CN2SW) Deviceet () PC/TB(CN2)(LEC-T1-)(LEC-W2)(LEC) TM(LEC) (CN2SW)Deviceet 15 - 4.3(LEC) (LEC)(LEC-T1-) (LEC-W2)(LEC) (LEC)(LEC)(LEC-T1-) 4.3.1 ID 2(LEC)ID (LEC)IDID112 ID (LEC-W2) Normal Parameter Controller ID () Download (IDID ) 4.3.2 IF(LEC)(LEC-T1) IF115.2kbps (LEC-W2) Normal HELP-Password 16 - Para protectComm speed -1 Para protect
-3G)(LEC-W2)(CN2SW)OFF (LEC-T1-3G)(LEC-W2) TB/PC (CN2) LED CN2 SW CN2STAT BUS STAT OFF (1) GW CN2 3m LEC-T1-3G (2) LEC-W2 USB CD GW 120.3 120.3 mm mm 200 200 mm/s mm/s USB 100 500 100 500 1 1 200 1000 200 1000 2 2 A-miniB type 50 200 50 200 3 3 CN2 CN2TB/PC 27 - 6.CN4 6.1 No.
IP65 compatible T1 S kit (With individual terminal blocks) kit (Serial transmission) Use as a guide for selection. Please confirm the actual conditions with SMC Sizing Program.
(Max. 20 stations) Applies to 45T/T1 only. 24VDC only for type S.
Q = qm x C x (T2 T1) x qv x C x iT 60 1 x 70 x 4.186 x 103 x 4.0 60 = = qm x C x (T2 T1) 860 Q = = 19535 [J/s] 19535 [W] = 19.5 [kW] x qv x 60 x C x iT 860 = Cooling capacity = Considering a safety factor of 20%, 19.5 [kW] x 1.2 = 23.4 [kW] 1 x 70 x 60 x 1.0 x 103 x 4.0 860 = Thermo-chiller T1: Outlet temperature Q: Heat generation amount 1680 [cal/h] 860 Users equipment = T = T2 T1
Q = qm x C x (T2 T1) x qv x C x iT 60 1 x 35 x 4.186 x 103 x 3.0 60 = = qm x C x (T2 T1) 860 Q = = 7325 [J/s] 7325 [W] = 7.3 [kW] x qv x 60 x C x iT 860 = Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 8.8 [kW] 1 x 35 x 60 x 1.0 x 103 x 3.0 860 = Q: Heat generation T1: Outlet Thermo-chiller temperature amount Customer equipment T = T2 T1 7325 [W] = 7.3 [kW]
Q = qm x C x (T2 T1) x qv x C x iT 60 1 x 35 x 4.186 x 103 x 3.0 60 = = qm x C x (T2 T1) 860 Q = = 7325 [J/s] 7325 [W] = 7.3 [kW] x qv x 60 x C x iT 860 = Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 8.8 [kW] 1 x 35 x 60 x 1.0 x 103 x 3.0 860 = Q: Heat generation amount T1: Outlet temperature Thermo-chiller Users equipment T = T2 T1 7325 [W] = 7.3 [kW] Cooling
[W] = 7.3 [kW] T = T2 T1 Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 8.8 [kW] T1: Outlet temperature 118 Cooling Capacity Calculation HRS100/150 Series Required Cooling Capacity Calculation Example 3: When there is no heat generation, and when cooling the object below a certain temperature and period of time.
1400 [W] T = T2 T1 Cooling capacity = Considering a safety factor of 20%, 1400 [W] x 1.2 = 1680 [W] T1: Outlet temperature 207 HRSE Series Required Cooling Capacity Calculation Example 3: When there is no heat generation, and when cooling the object below a certain temperature and period of time.
Q = qm x C x (T2 T1) x qv x C x iT 60 1 x 70 x 4.186 x 103 x 4.0 60 = = qm x C x (T2 T1) 860 Q = = 19535 [J/s] 19535 [W] = 19.5 [kW] x qv x 60 x C x iT 860 = Cooling capacity = Considering a safety factor of 20%, 19.5 [kW] x 1.2 = 23.4 [kW] 1 x 70 x 60 x 1.0 x 103 x 4.0 860 = Thermo-chiller T1: Outlet temperature Q: Heat generation amount 1680 [cal/h] 860 Users equipment = T = T2 T1
Q = qm x C x (T2 T1) x qv x C x iT 60 1 x 35 x 4.186 x 103 x 3.0 60 = = qm x C x (T2 T1) 860 Q = = 7325 [J/s] 7325 [W] = 7.3 [kW] x qv x 60 x C x iT 860 = Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 8.8 [kW] 1 x 35 x 60 x 1.0 x 103 x 3.0 860 = Q: Heat generation amount T1: Outlet temperature Thermo-chiller Users equipment 7325 [W] = 7.3 [kW] T = T2 T1 Cooling
[W] = 7.3 [kW] T = T2 T1 Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 8.8 [kW] T1: Outlet temperature 23 Cooing Capacity Calculation Series HRS100/150 Required Cooling Capacity Calculation Example 3: When there is no heat generation, and when cooling the object below a certain temperature and period of time.
Mark: 45T and T1 only S type is available for 24 VDC only. Nil CE-compliant CE-compliant X90 Main valve fluoro rubber (Refer to page 332.)
Nil FKM 1349-80*1 N1 EPDM 2101-80*1 P1 Barrel Perfluoro 70W Q1 Kalrez 4079 R1 Chemraz SS592 R2 SS630 R3 SSE38 S1 VMQ 1232-70*1 T1 FKM for Plasma 3310-75*1 *1 Values at normal temperature, excluding gas permeation *2 Refer to Construction on page 5 for changed part. Number corresponds with the parts number on the construction drawing.
-A5 V V ZP3PA-T1-AG1 V V ZP3PA-T2-A12 V V ZP3PA-T2-AG2 V V ZP3PA-T2-AG3 V V p. 11 w T female thread adapter Pad diameter Part no. 20 25 35 50 Dimensions w T male thread adapter assembly w T female thread adapter ZP3PA-T1-B5 V V ZP3PA-T2-B8 V V p. 11 q Pad unit Dimensions Part no.
Bore size (mm) 32, 40 50, 63 T2 T1 M F E D B Part No.
If sensor does not receive any signal within t1 (situation whereby the cylinder stops), this reflects homing is not achieved. Setting of response time should take into consideration of load, mounting condition, tubing length, etc. The response time should be re-calibrated, if the operating conditions change.