Conforming to OSHA Standard Pressure Relief 3 Port Valve With Locking Holes Series VHS20/30/40/50 Construction VHS20/30 VHS40/40-06/50 y i u w w t t r q IN OUT OUT IN q e o EXH. EXH. VM Component Parts No.
Language Choose English, Japanese, German, French, Italian, or Spanish ClockSet Set the Real Time Clock. s Other options that can be selected include: Press any key to enter the Top Menu where the Stop option is located. Enter this option to Stop the program and conrm with OK. Use the Run option to begin the program. Conrm with OK.
Inlet pressure (MPa) Weather resistant NBR Diaphragm assembly e 1315510A Flow Characteristics Inlet pressure: 0.7 MPa Valve assembly Valve spring Valve mini Y packing O-ring O-ring Handle Set nut Brass, HNBR Stainless steel NBR NBR NBR Polyacetal Zinc die-casted r t y u i o !
0.5 s/1 s/2 s/5 s Output protection Short-circuit protection Output mode Select from hysteresis mode, window comparator mode, accumulated output mode, or accumulated pulse output mode.
Mitsubishi Electric Corporation Yaskawa Electric Corporation Nil G R Y Lead screw type Ground ball screw Rolled ball screw Slide screw P N S Motor output 100W 2 Power supply voltage 100/110VAC (50/60Hz) 100/115VAC (50/60Hz) 200/220VAC (50/60Hz) 200/230VAC (50/60Hz) Without motor 1 The tables above show the definition for each symbol only and cannot be used for actual model selection. 2 0
FGDE Seal kit w, r, y, !3, !6: 1 pc. each FGDT FGDF u, o, !1, !2, !3, !4, !5, !6, !7 : 1 pc. each Note) Only the FGD-CA003 and CA005 includes !8 element guide in the set.
100 100 50 50 0 0 0 5 m/s m/s 19 4-3.
L S 1.0 x 101 B A 1 = m1 + m1 S 2 A2 + B2 12 A 2 Calculate the moment of inertia of the clamping jig. 2 = m2 + m2L2 D2 Arm: 1 Arm weight: m1 8 D
CRJ U 05 90 E F9B S With external stopper Number of auto switches Nil S 2 pcs. 1 pc.
Position of pivot:Axis , w P s 1 2 OSo||t dob. of pivot: Passes through the center ol gravity, parallel to Position of oivot: Diameter Position side b, s 1 2 ,_w 2f " s ' s oThh dhk Position of pivot: Passes through one end perpendicular to the plate. Position ot pivot:Diameter .r=W.ts s 4
Position of pivot:Axis , w P s 1 2 OSo||t dob. of pivot: Passes through the center ol gravity, parallel to Position of oivot: Diameter Position side b, s 1 2 ,_w 2f " s ' s oThh dhk Position of pivot: Passes through one end perpendicular to the plate. Position ot pivot:Diameter .r=W.ts s 4 World Wide QS\E Support...
CRJ U 05 90 E F9B S With external stopper Number of auto switches Nil S 2 pcs. 1 pc.
piLl lanp lighls wh6n hlo swilches a turned ON Eran0e P$s!
piLl lanp lighls wh6n hlo swilches a turned ON Eran0e P$s!
Configuration One thermo-chiller for one master. 2 2 R D R D 3 3 S D S D 5 5 S G S G Master This product Do not connect any wire to other PIN numbers. Fig. 3-14 Connection of RS-232C 3.3.10 Ethernet Modbus/TCP Communication wiring This product can operate the following by Ethernet Modbus/TCP communication.
Configuration One thermo-chiller for one master. 2 2 R D R D 3 3 S D S D 5 5 S G S G Master This product Do not connect any wire to other PIN numbers. Fig. 3-13 Connection of RS-232C HRL Series 3.3 Installation 3-27 HRX-OM-W060 Chapter 3 Transport and Setting Up 3.4 Piping Connect piping firmly.
Selection conditions Mounting: Horizontal Maximum speed: 500 mm/s Load eccentricity L1: 50 mm Overhang L: 30 mm Load mass m: 0.1 kg Refer to Graph 0 based on horizontal mounting, a speed of 500 mm/s and load eccentricity L1 of 50 mm.
I O N S AD S E R I E S A U I T O D R A I N S S Y M B O L S H O W T O O R D E R A U T O D R A I N S E R I E S AD AD402-02 (1/4) PT AD402-03 (3/8) PT AD402-04 (1/2) PT AD600-06 (3/4) PT AD600-10 (1) PT H O W T O O R D E R A U T O D R A I N S E R I E S NAD NAD402-N02 (1/4) NPT NAD402-N03 (3/8) NPT NAD402-N04 (1/2) NPT NAD600-N06 (3/4) NPT NAD600-N10 (1) NPT FOR FURTHER TECHNICAL DETAILS ON THIS
The value of the effective area S, like that of sonic conductance C, expresses the ease of flow. (3) Formula for flow rate When P2 + 0.1 0.5, choked flow P1 + 0.1 293 Q = 120 x S (P1 + 0.1) (3) 273 + t When P2 + 0.1 > 0.5, subsonic flow P1 + 0.1 293 Q = 240 x S (P2 + 0.1) (P1 P2) (4) 273 + t Conversion with sonic conductance C: S = 5.0 x C(5) Q : Air flow rate [dm3/min (ANR)], dm3
VXS VXS VXB VXE (3) Formula for flow rate When P2 + 0.1 0.5, choked flow P1 + 0.1 293 Q = 120 x S (P1 + 0.1) (3) 273 + T When P2 + 0.1 > 0.5, subsonic flow P1 + 0.1 293 Q = 240 x S (P2 + 0.1) (P1 P2) (4) 273 + T Conversion with sonic conductance C: VXP VXR VXH VXF VX3 VXA S = 5.0 x C(5) Q : Air flow rate[L/min(ANR)] S : Effective area [mm2] P1 : Upstream pressure [MPa] P2 : Downstream