I

Proof 65 3 Wire Output PNP 25 3 Wire Output NPN 26 3 Wire Analog Output P I P I N G S P E C I F I C AT I O N S 01 Direct Piping 1/8 PT T1 NPTF 1/8 H O W T O O R D E R P O S I T I V E P R E S S U R E S W I T C H S E R I E S ISE4 ISE4 B D W I R I N G S P E C I F I C AT I O N S O P E R AT I N G P R E S S U R E L Grommet Entry 3m Lead 0.6m -0.1 ~ 1MPa L -10 ~ 100KPa DIN R A I L M O U N T I N

Vacuum

Determine the mean suction flow: Q r = v x 6 o T1 9 9 0 . s : s : : P o o . g u o.z T 2 = 3 1 o 1 mean suction flow required from ejector (N/min), 0.1 0.2 0.3 0.5 0.7 1 2 3 | 5 7 10 20 30 50 70 100 O T1 i(sec) o1 adsorption response time to 63% to P, (sec), T1 adsorption response time to 95% of P" (sec), T2 1 l lncnnic System Specif ication (continued) 2.

Vacuum

Determine the mean suction flow: Q r = v x 6 o T1 9 9 0 . s : s : : P o o . g u o.z T 2 = 3 1 o 1 mean suction flow required from ejector (N/min), 0.1 0.2 0.3 0.5 0.7 1 2 3 | 5 7 10 20 30 50 70 100 O T1 i(sec) o1 adsorption response time to 63% to P, (sec), T1 adsorption response time to 95% of P" (sec), T2 1 l lncnnica System Specif ication (continued) 2.

Fluoropolymer Piping Equipment

M N LVQ 25 1 1/4 LVP Class 6 (E) Port size Class 2 to 5 R (NPT) LVW Metric sizes Inch sizes LQ1 LQ1 Connection threads R/NPT A E H L M N Min. port size W Connection threads R/NPT A E H L M N Min. port size W Model Applicable tubing O.D. Model Applicable tubing O.D.

Slider Type Ball Screw Drive/11-LEFS Series

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 [s] T = T1 + T2 + T3 + T4 [s] L 0.5 V (T1 + T3) V T1: Acceleration time and T3: Deceleration time can be obtained by the following equation.

1

U S Z NS NZ Non-polar r Pilot type Positive common Nil R Internal pilot External pilot !

Table of Contents

1/8 23.4 27.4 39.8 45.8 17.6 14 R 1/4 25.4 31.4 39.8 45.8 17.6 12 R 1/8 26.7 30.7 45.3 52.8 24 14 R 1/4 28.7 34.7 45.3 52.8 24 17 R 3/8 30.4 36.7 45.3 52.8 24 17 R 1/4 33.8 39.8 49.6 55.6 30 17 R 3/8 35.5 41.8 49.6 55.6 30 22 R 1/2 37.6 45.8 49.6 55.6 30 Dimension with cover Reference dimension of R thread after installation.

Electric Actuators

LC1-1-S1 PC-98 (MS-DOS) LC1-1-W1 (Windows 95 Japanese) LC1-1-W2 (Windows 95 English) and LC1-1-R (dedicated communication cable) (Refer to pages 194, 195, and 199.) or LC1-1-T1(Teaching box) are required.

SX

S 5 VDC R 3 VDC 1-6-55 56 Manifold Specifications SS5X3-41 SS5X3-42 SS5X5-41 SS5X5-42 SS5X7-42 SX340 SX340(R) SX540 SX540(R) SX740(R) Single base/B mount Common SUP/Common EXH 2 to 20 stations Base Side Rc 1 8 Rc 1 8 Rc 1 8 Rc 1 4 Rc 1 4 Model Applicable valve Manifold type P(SUP)/R(EXH) Valve stations Note) Location Direction A, B Porting specifications P, EA, EB port Rc 1 4 Rc 1 4 M5 x

SY

Scale: 25% For external pilot specification (Pitch) P = 24 24.3 22.2 11 18.3 3/5 R 3/5 R A 4 A 4 A 4 A 4 A 4 A 4 40.1 39.3 18.8 18 18.8 3/5 R 3/5 R A 4 A 4 A 4 A 4 A 4 A 4 39.3 63.3 79.8 1 P 1 P B 2 B 2 B 2 B 2 B 2 B 2 2-Plug 1 P 1 P B 2 B 2 B 2 B 2 B 2 B 2 [1 (P), 3/5 (R) port] 2-One-touch fitting One-touch fitting 2n1-One-touch fitting [1 (P), 3/5 (R) port] Applicable tube O.D.: 12 [PE:

Integrated Controller

Calculation example) T1 to T4 can be calculated as follows. L Speed: V [mm/s] a1 a2 T1 = V/a1 = 300/10 = 0.03 [s], T3 = V/a2 = 300/10 = 0.03 [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.

Environment

0 i o e r t q u !1 !2 !3 !

Compact

T1 = V/a1 = 1000/2500 = 0.4 [s], T1 T2 T3 T4 11LEJS T3 = V/a2 = 1000/2500 = 0.4 [s] L: Stroke [mm](Operating condition) V: Speed [mm/s](Operating condition) a1: Acceleration [mm/s2](Operating condition) a2: Deceleration [mm/s2](Operating condition) T = T1 + T2 + T3 + T4 [s] L 0.5V(T1 + T3) V 25AT2 = T1: Acceleration time and T3: Deceleration time can be obtained by the following equation

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

30 50 Lead 8: LEKFS32(L/R)EB Lead 8: LEKFS32(L/R)EB 40 Work load: W [kg] Work load: W [kg] 20 30 Lead 16: LEKFS32(L/R)EA Lead 16: LEKFS32(L/R)EA 20 10 Lead 24: LEKFS32(L/R)EH Lead 24: LEKFS32(L/R)EH 10 0 0 0 200 400 600 800 1000 1200 0 100 200 300 400 500 600 Speed: V [mm/s] Speed: V [mm/s] Vertical LEKFS40(L/R)/Ball Screw Drive Horizontal 70 60 30 Lead 10: LEKFS40(L/R)EB Lead 10: LEKFS40

5 Port Solenoid Valve Series SY3000/5000/7000/9000

P R R P R R L (10) 8 End plate side End plate side (24) (35) 5.5 Silencer with One-touch fitting The silencer plugs directly into the One-touch fittings of the manifold.

Thermo-chiller

W: 5.1 [kW] r Calculate based on the laser output.

HRS100/150

Applicable model Minimum operating flow rate [L/min] (50/60 Hz) HRS-BP007 HRS100-28/42 HRS150-q To circulating fluid return port y To circulating fluid outlet r t w u r t r e r Parts List No.

Thermo-chiller

Applicable model HRS-BP008 HRS100HRS150q To circulating fluid outlet To circulating fluid return port r t w y r u r t r e Parts List No.

ZSE2/ISE2

1/8 T1: NPTF 1/8 01: R 1/8 T1: NPTF 1/8 IF Data 16-6-13

HRL

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