ZP

ZPA-T1-B01 ZPA-T1-N01 ZPA-T1-T01 ZPA-T2-B01 ZPA-T2-N01 ZPA-T2-T01 ZPA-T2-B01 ZPA-T2-N01 ZPA-T2-T01 ZPA-T3-B01 ZPA-T3-N01 ZPA-T3-T01 ZPA-T3-B01 ZPA-T3-N01 ZPA-T3-T01 ZPA-T1-B8 ZPA-T1-B10 ZPA-T1-B8 ZPA-T1-B10 ZPA-T2-B8 ZPA-T2-B10 ZPA-T2-B12 ZPA-T2-B16 ZPA-T2-B8 ZPA-T2-B10 ZPA-T2-B12 ZPA-T2-B16 ZPA-T3-B12 ZPA-T3-B16 ZPA-T3-B12 ZPA-T3-B16 ZP40 ZP40 With three M3 bolts With three M3 bolts ZP50

2

(mm) Connection thread Rc Model T (M) Weight (g) NylonUrethane 3.2 1/4 KQ2E23-02l M12 x 1 17 14 28.7 14.3 13 13.3 3.4 2.9 2.5 31.2 Applicable tubing Mounting plate thickness 7 mm or less 4 1/8 KQ2E04-01l M12 x 1 14 14 24.4 10 13 13.3 5.6 4 3 21.2 1/4 KQ2E04-02l M12 x 1 17 14 29 14.6 13 13.3 5.6 4 3 30.9 H1 H2 T 6 1/8 KQ2E06-01l M14 x 1 17 17 23.6 9.2 15 13.3 13.1 10.4 4.5 28.9 1/4 KQ2E06-

Battery-less

LECSN-T1 LECSS-T1 Compliance No.

Electric Actuator/Slider Type

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 obtained by the following equation.

HRX-OM-W002

If Option T is selected, Option T1 cannot be selected.

15

L Speed: V [mm/s] Calculation example) T1 to T4 can be calculated as follows. a1 a2 Time [s] T1 = V/a1 = 300/3000 = 0.1 [s], T3 = V/a2 = 300/3000 = 0.1 [s] T = T1 + T2 + T3 + T4 [s] T1 T2 T3 T4 L 0.5 V (T1 + T3) V T1: Acceleration time and T3: Deceleration T2 = L : Stroke [mm] time can be obtained by the following equation. 200 0.5 300 (0.1 + 0.1) 300 (Operating condition) V : Speed

ZP

ZPA-T1-B01 ZPA-T1-N01 ZPA-T1-T01 ZPA-T2-B01 ZPA-T2-N01 ZPA-T2-T01 ZPA-T2-B01 ZPA-T2-N01 ZPA-T2-T01 ZPA-T3-B01 ZPA-T3-N01 ZPA-T3-T01 ZPA-T3-B01 ZPA-T3-N01 ZPA-T3-T01 ZPA-T1-B8 ZPA-T1-B10 ZPA-T1-B8 ZPA-T1-B10 ZPA-T2-B8 ZPA-T2-B10 ZPA-T2-B12 ZPA-T2-B16 ZPA-T2-B8 ZPA-T2-B10 ZPA-T2-B12 ZPA-T2-B16 ZPA-T3-B12 ZPA-T3-B16 ZPA-T3-B12 ZPA-T3-B16 ZP40 ZP40 With three M3 bolts With three M3 bolts ZP50

AC Servo Motor Driver LECYM/LECYU Series Compatible LEF  Position control, speed control and torque control Power supply voltage (V) LEJ can be used. 200 to 230 VAC 
Control encoder: Absolute 20-bit encoder LEL Motor capacity (W) (Resolution: 10485

L Calculation example) T1 to T4 can be calculated as follows. Speed: V [mm/s] a1 a2 T1 = V/a1 = 300/3000 = 0.1 [s], Time [s] T3 = V/a2 = 300/3000 = 0.1 [s] T = T1 + T2 + T3 + T4 [s] L 0.5 V (T1 + T3) V T1 T2 T3 T4 T1: Acceleration time and T3: Deceleration time can be obtained by the following equation.

HRX-OM-X084

Circulating fluid flow rate [L/min] Fig 9-13 Pump capacity(HRR010-A/W-10/20) 9.6.2 HRR010-A/W-10/20-T1 0.40 0.35 Outlet Allowable 0.30 operating range Pressure [MPa] 0.25 Return port 0.20 Return port 0.15 for option Z1 Allowable 0.10 operating range Return port for option Z 0.05 0.00 0 2 4 6 8 10 12 14 16 18 20 Circulating fluid flow rate [L/min] Fig 9-14 Pump capacity(HRR010-A/W-10/20-T1

ZP

tubing: 6 Applicable tubing: 6 Applicable tubing: 6 Width across flat 14 Width across flat 14 Width across flat 14 2 2 2 2 2 2 7 18 12 12 18 18 12 M12 x 1 M12 x 1 M12 x 1 33.2 33.2 Width across flat 14 Width across flat 14 Width across flat 14 7 5 5 5 7 1.8 1.8 1.8 1 1.2 1.2 10 13 16 11 14 17 9 With Adapter: Vacuum Inlet Series ZP3 Vertical 4 to 8 Pad diameter Vertical Dimensions/With Adapter

Vacuum Pad

tubing: 6 Applicable tubing: 6 Applicable tubing: 6 Width across flat 14 Width across flat 14 Width across flat 14 2 2 2 2 2 2 7 18 12 12 18 18 12 M12 x 1 M12 x 1 M12 x 1 33.2 33.2 Width across flat 14 Width across flat 14 Width across flat 14 7 5 5 5 7 1.8 1.8 1.8 1 1.2 1.2 10 13 16 11 14 17 9 With Adapter: Vacuum Inlet Series ZP3 Vertical 4 to 8 Pad diameter Vertical Dimensions/With Adapter

Thermo-chiller/Rack Mount Type

The weight will increase by 2 kg when Option T1 (Inverter pump mounted) is selected. 12 Option M (Applicable to DI water piping) does not contain copper. 13 For Option DM (With electric conductivity control function, Applicable to DI water piping) 14 If the product is used at an altitude of 1000 m or higher, refer to For altitudes of 1000 m or higher on page 42. 15 No continuous voltage

CATALOG

Fixed Eye (1.5 to 14) C MP4 Single Detachable Rear Clevis/Male (1.5 to 14) L MS1 Foot Mount (1.5 to 14) S MS2 Side Lug (1.5 to 14) O MS3 Centerline Lug (1.5 to 14) R MS4 Side-Tapped (1.5 to 14) P .MS7 Front Lug Mount (1.5 to 14) J MT2 Cap Trunnion (1.5 to 14) U MT1 Head Trunnion (1.5 to 14) T MT4 Center Trunnion (1.5 to 14) *See below B MX0 Basic/No Mount (1.5 to 14) BA .

Table of Contents

Average suction flow rate V x 60 T1 V x 60 T1 Q = Q = + QL T2 = 3 x T1 T2 = 3 x T1 Q : Average suction flow rate /min (ANR) V : Piping capacity () T1 : Arrival time to stable Pv 63% after adsorption (sec.) T2 : Arrival time to stable Pv 95% after adsorption (sec.) QL : Leakage at work adsorption /min (ANR) 2.

42

installed) D side entry (LD) 216 with AMC610-10 installed ( 261.5 with AMC810-14 installed) U side D side U side D side =100 with AMC610-10 installed 100 with AMC610-10 installed 100 with AMC610-10 installed = 100 with AMC610-10 installed 118 (135) (=105 with AMC810-14 installed) ( 105 with AMC810-14 installed) 118 (135) 159 (172.5) (105 with AMC810-14 installed) (= 105 with AMC810-14

VQ5000

Note 2) Splash proof specification is not available for F and T1.

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.

HRX-OM-X071

,T2Inverter pump 6.3.1 Option T1, T2Inverter pump With option T1 or T2, the pump output set value can be changed.

Controller/Driver LEC/JXC Series <Single Axis Controllers> Step Data Input Type Page 560 Gateway Unit Page 572 Programless Type Page 576 Step Motor LEC-G Series Step Motor Servo Motor (Servo/24 VDC)/ (Servo/24 VDC)/ (24 VDC)/ LECP6 Series LE

(Robotic cable only) Cable type Actuator side (14) (18) (Terminal no.)

Environment

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.