3 Port Solenoid Valve, VQ100 Series, Base Mounted Type

How to Calculate Flow (At an air temperature 20C) 1P1+0.1013<1.89(P2+0.1013) Q=226S P(P2+0.1013) Piping 2P1+0.10131.89(P2+0.1013) 1Completely flush (air blow) pipes before plumbing to remove dust. 2Clamping torgue: Q=113S(P1+0.1013) Q:Flow rate under standard conditions [ /min (ANR)] P1:Upstream pressure (MPa) P2:Downstream pressure(MPa) P:Pressure differential(P1-P2)(MPa) S:Effective area

Series VC, Series VCS, Direct Operated 2 Port Solenoid Valve for Steam

For subsonic range Where P1 + 0.1013 = (1 to 2) (P2 + 0.1013) Formula based on Cv factor Q = 197.8Cv P (P2 + 0.1013) kg/h Formula based on effective area Q = 11.0S P (P2 + 0.1013) kg/h [650] (133) 0.2 [646] (120) 0.1 S = 2.8mm S = 5.9mm S = 9.2mm S = 11.7mm S = 6.3mm S = 9.7mm S = 14.4mm S = 10.8mm S = 15.3mm S = 24.8mm Flow rate Q kg/h VCS212 VCS213 VCS214 VCS215 VCS 13 VCS314 VCS315

Air Slide Table

A B C D1 E F G M (Fine pitch) P2 MXQ6(L, A) MXQA-AS8-X2202 41.5 2.5 3 M3 x 12 18 5.8 8.3 M6 x 0.75 M3 x 6 MXQ8(L, A, C, CL) MXQ6B(L) MXQ12(L, A, C, CL) MXQ8B(L) MXQA-AS12-X2202 46.5 2.5 4 M3 x 12 24 7.1 10.4 M8 x 1 M4 x 8 MXQ16(A) MXQ12B(L) MXQA-AS16-X2202 51.5 3 5 M4 x 12 29.4 9.2 12.6 M10 x 1 M5 x 10 MXQ20(A) MXQ16B MXQA-AS20-X2202 58.5 4 6 M5 x 12 36 11.2 16.2 M12 x 1 M6 x 12 MXQ25(A)

Air Catch Sensor

Remove the gauge and balance the bridge circuit (P1 = P2) by adjusting the variable orifice (S3) via the adjustment knob. By moving the work piece away from the nozzle (S4) a pressure differential (P1 P2) is created. As soon as the work piece is moved within the detection range of the AirCatch Sensor the back pressure P2 increases.

Soft Start-up Valve AV2000/3000/4000/5000 1

How to Find the Flow Rate (At air temperature of 20C) Choke flow: (P2 + 0.1)/(P1 + 0.1) ) 0.5 293 273 + t Q = 120 x S x (P1 + 0.1) x Subsonic flow: when (P2 + 0.1)/(P1 + 0.1) > 0.5 Q = 240 x S x (P1 P2)(P2 + 0.1) x 293 273 + t Q: Air flow rate [ /min (ANR)] S: Effective area (mm2) P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] t: Air temperature [C] Note 1) Formulas above are

VER2000/4000

Subsonic flow at P1 + 0.1013 < 1.89 (P2 + 0.1013) Q = 226S P (P2 + 0.1013) Sonic flow of P1 + 0.1013 1.89 (P2 + 0.1013) Q = 113S (P1 + 0.1013) VER2000 Q: Air flow rate [/min (ANR)] S: Effective area [mm2] P: Amount of pressure drop P1 P2 [MPa] P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] Cylinder stroke (st/mm) Correction for varying air temperatures: Square the coefficient

Series DXT474

Q=226S P(P2+0.1013) Sonic flow : P1+0.10131.89(P2+0.1013) Q=113S(P1+0.1013) Q : Flow rate [ /min(ANR)] S : Effective area (mm2) P : Pressure differential (P1-P2) [MPa] P1 : Upstream pressure [MPa] P2 : Downstream pressure [MPa] When the air temperature is different, multiply the flow rate calculated with the above formula by the following coefficient for compensation. -20 1.08 -10 0 10 30

SY

How to Find the Flow Rate (at air temperature of 20C) Subsonic flow when P1 + 0.1013 < 1.89 (P2 + 0.1013) Q = 226S P(P2 + 0.1013) Sonic flow when P1 +0.1013 1.89 (P2 + 0.1013) Q = 113S (P1 + 0.1013) Q : Air flow rate [l/min (ANR)] S : Effective area (mm) P : Pressure drop (P1 P2) [MPa] P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] Correction for different air temperatures Multiply

SZ3000

How to Find the Flow Rate (at air temperature of 20C) Subsonic flow when P1 + 0.1013 < 1.89 (P2 + 0.1013) Q = 226S P(P2 + 0.1013) Sonic flow when P1 +0.1013 1.89 (P2 + 0.1013) Q = 113S (P1 + 0.1013) Q: Air flow rate [l/min(ANR)] S: Effective sectional area (mm) P: Differential pressure (P1-P2) [MPa] P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] Correction for different air temperatures

Series VCS

For subsonic range Where P1 + 0.1013 = (1 to 2) (P2 + 0.1013) Formula based on Cv factor Q = 197.8Cv P (P2 + 0.1013) kg/h Formula based on effective area Q = 11.0S P (P2 + 0.1013) kg/h [650] (133) 0.2 [646] (120) 0.1 S = 2.8mm S = 5.9mm S = 9.2mm S = 11.7mm S = 6.3mm S = 9.7mm S = 14.4mm S = 10.8mm S = 15.3mm S = 24.8mm Flow rate Q kg/h VCS212 VCS213 VCS214 VCS215 VCS 13 VCS314 VCS315

VKF300

How to Find the Flow Rate (at air temperature of 20C) Subsonic flow when P1 + 0.1013 < 1.89 (P2 + 0.1013) Q = 226S P(P2 + 0.1013) Sonic flow when P1 +0.1013 1.89 (P2 + 0.1013) Q = 113S (P1 + 0.1013) Q: Air flow rate [l/min(ANR)] S: Effective area (mm) P: Pressure drop (P1-P2) [MPa] P1: Upstream pressure [MPa] P2: Downstream pressure [MPa] Maintenance Correction for different air temperatures

VXA21/22

(P2+0.1013) Calculation by Cv factor Q=1972.8.Cv.

Microprocessor-Controlled Electro-Pneumatic Regulator ITV2000 EASY PROGRAMMING GUIDE

Maximum load current: 30mA The NPN and PNP digital monitor outputs can be set to function in one of three different ways: comparator mode hysteresis mode self-diagnostic mode when P1<P2 when P1>=P2 when P1=P2=0 The output is on whenever the outlet pressure is greater than P1 but less than P2. The output comes on once the outlet pressure reaches P1.

Size: 42.5 O.D., Display Pressure: 0.2MPa, 30psi, Connection Thread: R 1/8, Clear Cover Material: Polycarbonate, Attachment: Clear Cover Removable, Wrench Tighten, Option: Both MPa and psi

Size: 42.5 O.D., Display Pressure: 0.2MPa, 30psi, Connection Thread: R 1/4, Clear Cover Material: Polycarbonate, Attachment: Clear Cover Removable, Wrench Tighten, Option: Both MPa and psi

Size: 42.5 O.D., Display Pressure: 0.2MPa, 30psi, Connection Thread: R 1/8, Clear Cover Material: Polycarbonate, Attachment: Clear Cover Removable, Hand Tighten, Option: Both MPa and psi

60

SUP. 3 1 2 3 1 2 3 1 2 E Padlock mounting position D C SUP J 2 2 x K A T IN OUT AA 3 L 2 x P1 (Port size) B V BB U Built-in silencer (Option) M (Width across flats) 3 N P2 (Port size) Q EXH Y Bracket (Option) R S X W Dimensions (mm) Standard specifications Model P1 P2 A B C D E F G H I J K L M 1/8, 1/4 1/4, 3/8 1/8 1/4 3/8 1/2 1/2 66.4 80.3 104.9 110.4 134.3 22.3 29.4 38.5 42 53 40 53 70

E-P HYREG

IRV 2 VEX 1(P) 3(R) 2(A) Simplified main circuit n SRH SRP 1 SRF 3(R) 2 ITV Simplified pilot circuit 1(P) 2(A) P2 P1 3(R) 1(P) IC 1(P) 2(A) n E-P HYREG Ease of handling ITVH Having the amplifier built into the electro-pneumatic pilot valve, only an external power supply and signal (voltage, current) need to be connected.

RZQ

P2 = 1.5 x 0.5-0.024 x 15 = 0.39 MPa Retraction r RHC The above values are for cases where the maximum payload found by the selection method is loaded. 0.2 MK(2) 0.1 100 200 300 Speed adjustment RS Q G Max. speed (mm/s) The data below illustrates the strokes controlled by the respective speed controllers. Gradually increase from a low speed to the desired speed setting.

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

Motor power supply (+), Common () @1 P1, P2 EtherNet/IPTM communication connector Connect Ethernet cable. 1 Connectors are included. (Refer to page 606-7.) 606-6 B JXC73/83/92/93 Series Wiring Example 1 For 4 Axes 1 pc.