ITVH AP100 Port size B 2 1/4 3 3/8 Note) EXH port: 1/4 Built-in regulator EXH port: M5 Solenoid valve EXH port: M5 L-bracket C * Bracket is included. 957 ITVH2000 Series Standard Specifications Model ITVH2000 Minimum supply pressure Whichever is higher: 0.5 MPa or the set pressure + 0.2 MPa Maximum supply pressure 3.0 MPa Set pressure range Note 1) 0.2 to 2.0 MPa Power supply Voltage 24 VDC 10%
10.2 8 10 17.8 11 5.5 2-3.3 Mounting hole Connector type: ZSP10X C Adjusting needle ADJ Pressure sensor Vacuum supply port 20 08 Adsorption nozzle port 7 48.3 Lead wire length 600 (3000) Adsorption nozzle port 0X: M5 x 0.8 0XY: M6 x 1 Vacuum supply port 0X: M5 x 0.8 0XY: M6 x 1 59.5 50 PV 6.5 10.2 8 5.5 17.8 11 10 2-3.3 Mounting hole 16-7-4
View A-A Bore size (mm) Stroke range (mm) AF AE AD AC AB AA A G F E D C B AP H 20 25 32 40 50 75, 100, 125, 150, 200 25 62 15.5 13 11 84 5.6 90 45 24 106 M5 x 0.8 depth 10 9.5 depth 6 22 M6 x 1 depth 10 30 65 16.5 13 15 89 6.8 103 45 26.5 120 11 depth 8 M6 x 1 depth 12 M8 x 1.25 depth 14 27 75, 100 125, 150 200, 250 300 35 70 16.5 13 15 94 6.8 118 50 26.5 135 11 depth 8 M6 x 1 depth 12 M8
Center Trunnion Style: CA2T With rod boot Z + 1/2Stroke Width across flats KA 4 x J G G 2 x P (Rc, NPT, G) 2 x cushion valve MM TDe8 D E e TY B C d B1 f 10.2 l H1 B C AL h + l K A N F TT N ZZ + l + Stroke TX TZ S + Stroke H ZZ + Stroke (mm) Stroke range (mm) A Bore size (mm) AL B B1 C D E F G H1 J K KA MM N P Without rod boot With rod boot 40 Up to 500 20 to 500 30 27 60 22 44 16 32 10 15
Symbol: A0 Symbol: A1 Symbol: A2 Symbol: A3 C DA C0.5 30 30 A H H T H H W1 WA C Approx.
0 kPa 5 kPa X580 10 kPa -10 kPa 0 kPa 10 kPa -60No.PS-OMV1001-C
Dimensions Body dimensions -61No.PS-OMV1001-C
Mounting brackets Bracket A Bracket B -62No.PS-OMV1001-C
Bracket C -63No.PS-OMV1001-C
Panel mount adapter Panel mount adapter + Front protective cover -64No.PS-OMV1001-C
Panel cut-out dimensions Single Pressure switch Two or more in a row n: The number of the Pressure switch
60% Ethylene Glycol Physical property value Temperature Density Specific heat C [kg/m 3] [g/l] ([kcal/kg C]) [J/(kgK)] 1.10 x 10 3 3.02 x 10 3 (0.72) 10C 1.08 x 10 3 3.15 x 10 3 (0.75) 20C 1.06 x 10 3 3.27 x 10 3 (0.78) 50C 1.04 x 10 3 3.40 x 10 3 (0.81) 80C Water Density : 1 x 10 3 [kg/m 3] [g/l] Specific heat C: 4.2 x 10 3 [J/(kgK)] (1.0 [kcal/kg C]) 79 Thermo-chiller Series HRZ Fluorinated
V : 150 [L] Cooled substance specific heat C : 1.0 x 103 [cal/(kgfC)] HRS 100/150 HRS 100/150 HRSH 090 HRSH Cooled substance temperature when cooling begins T0 : 30 [C] Cooled substance temperature after t hour Tt : 20 [C] Cooling temperature difference iT : 10 [C] (= T0 Tt) Cooling time it : 15 [min] Conversion factor: hours to minutes : 60 [min/h] Conversion factor: kcal/h to kW : 860
-COM1-COM2 (b) I/O 2 20K (a) +COM3+COM4 (c (b) BUSY1BUSY4 AREA1AREA4 INP1 ) INP4*ALARM1 *ALARM4 (c) -COM3-COM4 -PNP I/O 1 (a) +COM1+COM2 (b) OUT0 OUT8 BUSY AREA SETON (a) INPSVRE *ESTOP*ALARM (c) -COM1-COM2 10K I/O 2 (b) 4.7K (a) +COM3+COM4 (c) BUSY1 BUSY4AREA1 AREA4 (b) INP1 INP4 *ALARM1 *ALARM4 (c) -COM3-COM4 37 No.SFOD-OMT0009CN-B 6.3 No.
ratio : 1 [kgf/L] Circulating fluid (volume) flow rate qv : 70 [L/min] Circulating fluid specific heat C : 1.0 x 103 [cal/(kgfC)] Circulating fluid outlet temperature T1 : 20 [C] Circulating fluid return temperature T2 : 24 [C] Circulating fluid temperature difference iT : 4 [C] (= T2 T1) Conversion factor: hours to minutes : 60 [min/h] Conversion factor: kcal/h to kW : 860 [(cal/h)/W]
Q = qm x C x (T2 T1) x qv x C X T 1 x 35 x 4.186 x 103 x 3.0 60 = = 60 qm x C x (T2 T1) 860 Q = = 7325 [J/s] 7325 [W] = 7.3 [kW] x qv x 60 x C x T = Cooling capacity = Considering a safety factor of 20%, 7.3 [kW] x 1.2 = 860 8.8 [kW] 1 x 35 x 60 x 1.0 x 103 x 3.0 860 = Thermo-chiller qv: Circulating fluid flow rate Q: Heat generation amount T2: Return temperature Users equipment 7325
2-A 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 1-C 2-B 2-B 2-B 1-A 1-B 1-C 2-A 2-B 1-C 2-A 2-B 2-B 2-B 2-B 2-B 1-A 1-B 1-C 2-A 2-B 2-B 2-B 2-B 2-B 2-B Courtesy of Steven Engineering, Inc.-230 Ryan Way, South San Francisco, CA 94080-6370-Main Office: (650) 588-9200-Outside Local Area: (800) 258-9200-www.stevenengineering.com 6 1/8, 1/4 500 1.5 0 1,000 2,000 3,000 6
Leakage voltage Take note that the leakage voltage will increase when a resistor is used in parallel with switching element or a C-R circuit (surge voltage suppressor) is used for protecting a switching device because of the passing leakage voltage through the C-R circuit. The suppressor residual leakage voltage should be as 3% or less of the rated voltage. 3.
t signai VDC 1 2 3 Input signalVDC 1 2 3 Hysteresis r c 0.5 z o E ! 0 E E ,o5 5 E 1 2 3 4 lnplrl signal VDC lrpul signa VDC 1 2 3 lnput slgna!
type snap ring for shaft C type snap ring for shaft C type snap ring for shaft Return spring 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 Clear anodized Clear anodized 20, 32 only 20, 32 only Nickel plated Nickel plated Hexagon socket head set screw Hexagon socket head set screw 20 only Nickel plated 20 only Hexagon socket head plug Spring pin Wear ring
t signai VDC 1 2 3 Input signalVDC 1 2 3 Hysteresis r c 0.5 z o E ! 0 E E ,o5 5 E 1 2 3 4 lnplrl signal VDC lrpul signa VDC 1 2 3 lnput slgna!
The maximum piston speed for retraction is approximately 70% that of extension. 848 Dual Rod Cylinder/Compact Type CXSJ 2122CXSJ/ 1112Auto Switch Proper Mounting Positions (Detection at Stroke End) CXSJ6 / CXSJ6 11122122D B (mm) D-M9 23 (24) 2 (1) 13 (11.5) 8 (9) D-A93 19 (20) 14.5 (15.5) 6.5 (7.5) Symbol A B C D Note 1) A C Note 1) The above mentioned values are indicated as a guide for