Digital Flow Switch (Remote type monitor unit) . -14No.PF-OMN0012-H Mounting and Installation Installation Mounting with panel mount adapter Fix the panel mount adapter to the flow monitor with the screws supplied M3 x 8 L (2 pcs.).
Water hammer Window comparator mode An operating mode in which the switch output is turned on and off depending on whether the flow is inside or outside the range of two set values -12No.LFE*-OMZ0013 Mounting and Installation Installation Mounting by panel mount adapter Fix the panel mount adapter to the controller by the mounting screws M3 x 8L (2 pcs.).
(Recommend using an M3 Phillips head screwdriver with magnet.) Disconnect the piping on top and bottom of the valves and remove the connector for wiring. Replace the valves with new ones. Note) Notes: Mounting orientation of the valves is specified. Make sure that the connector for wiring should be on the upper side of the valve.
(Recommend using an M3 Phillips head screwdriver with magnet.) Disconnect the piping on top and bottom of the valves and remove the connector for wiring. Replace the valves with new ones. Note) Notes: Mounting orientation of the valves is specified. Make sure that the connector for wiring should be on the upper side of the valve.
Dynamic viscosity [m2/s] Viscosity [Pas] Density [kg/m3] Viscosity and dynamic viscosity are obtained by the formulas below. Dynamic viscosity [cSt] Viscosity [mPas] Density [g/cm3] 1 [mPas1 [cP] 13 Working Principle 1. When air is supplied, it passes through the switching valve and enters drive chamber B. 2.
Dynamic viscosity [m2/s] Viscosity [Pas] Density [kg/m3] Viscosity and dynamic viscosity are obtained by the formulas below. Dynamic viscosity [cSt] Viscosity [mPas] Density [g/cm3] 1 [mPas1 [cP] 14 Working Principle 1. When air is supplied to P1 port, it enters drive chamber A. 2. Diaphragm A moves to the left, and at the same time diaphragm B also moves to the left. 3.
Dynamic viscosity [m2/s] Viscosity [Pas] Density [kg/m3] Formulas below can be used for common units 1cP = 1mPas = 10-3Pas 1cSt = 1mm2/s = 10-6m2/s 13 Working Principle 1. When air is supplied, it passes through the switching valve and enters drive chamber B. 2.
Dynamic viscosity [m2/s] Viscosity [Pas] Density [kg/m3] Formulas below can be used for common units 1cP = 1mPas = 10-3Pas 1cSt = 1mm2/s = 10-6m2/s 14 Working Principle 1. When air is supplied to P1 port, it enters drive chamber A. 2. Diaphragm A moves to the left, and at the same time diaphragm B also moves to the left. 3.
Dynamic viscosity [m2/s] Viscosity [Pas] Density [kg/m3] Formulas below can be used for common units 1cP = 1mPas = 10-3Pas 1cSt = 1mm2/s = 10-6m2/s Pulsation Attenuating Capacity The process pump generates pulsation because it discharges a liquid using two diaphragms.
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Heat Differential temp. of 3 oC Differential temp. of 6 oC Radiated Model between inside and outside between inside and outside kW of installation area of installation area HRS012-AApprox. 2 40 20 HRS018-AApprox. 4 70 40 HRS024-A-20 Approx. 5 90 50 The water-refrigerated thermo-cooler discharges heat
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Differential temp. of 3 oC Differential temp. of 6 oC Heat Radiated between inside and between inside and Model kW outside of installation outside of installation area area HRS018-A-20--R Approx. 4 70 40 HRS030-A -20--R Approx. 6 100 60 3.2 Installation HRS-R Series 3-6 HRX-OM-W058 Chapter 3 Transport
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Differential temp. of 3 oC Differential temp. of 6 oC Heat Radiated between inside and between inside and Model kW outside of installation outside of installation area area HRS050-A-20--R Approx. 10 140 70 3.2 Installation HRS-R Series 3-6 HRX-OM-X027 Chapter 3 Transport and Setting Up 3.2.3 Installation
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Heat Differential temp. of 3 oC Differential temp. of 6 oC Radiated Model between inside and outside between inside and outside kW of installation area of installation area HRS030-A-20 Approx. 6 100 60 The water-refrigerated thermo-cooler discharges heat by using facility water.
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Differential temp. of 3 oC Heat Differential temp. of 6 oC Radiated between inside and Model between inside and outside kW outside of installation of installation area area HRS040-A-20 Approx.8 120 70 The water-refrigerated thermo-cooler discharges heat by using facility water.
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Differential temp. of 3 oC Heat Differential temp. of 6 oC Radiated between inside and Model between inside and outside kW outside of installation of installation area area HRS050-A-20 Approx.10 140 70 The water-refrigerated thermo-cooler discharges heat by using facility water.
Table 3-1 Amount of radiation and required ventilation Required ventilation amount m3/min Differential temp. of 3 oC Heat Differential temp. of 6 oC Radiated between inside and Model between inside and outside kW outside of installation of installation area area HRS060-A-20 Approx.12 200 100 The water-refrigerated thermo-cooler discharges heat by using facility water.
Table 3.2-1 Amount of radiation and required ventilation Required ventilation amount (m3/min) Heat Differential temp. of Differential temp. of Model radiation 3 oC between inside and 6 oC between inside and (kW) outside of installation outside of installation area area HRS400-A-46Approx.52 865 435 Installation environment specifications Sound noise: HRS400-A-46 : 71 dB(A) Front 1m, height
Table 3.2-1 Amount of radiation and required ventilation Required ventilation amount (m3/min) Heat Differential temp. of Differential temp. of Model radiation 3 oC between inside and 6 oC between inside and (kW) outside of installation outside of installation area area HRL100-A-20 Approx.18 305 155 HRL200-A-20 Approx.35 590 295 HRL300-A-20 Approx.45 760 380 Installation environment specifications
Table 3.2-1 Amount of radiation and required ventilation Required ventilation amount (m3/min) Heat Differential temp. of Differential temp. of Model radiation 3 oC between inside and 6 oC between inside and (kW) outside of installation outside of installation area area HRL100-A-20 Approx.18 305 155 HRL200-A-20 Approx.35 590 295 HRL300-A-20 Approx.45 760 380 Installation environment specifications
Table 3.2-1 Amount of radiation and required ventilation Required ventilation amount (m3/min) Heat Differential temp. of Differential temp. of Model radiation 3 oC between inside and 6 oC between inside and (kW) outside of installation outside of installation area area HRL100-A-40 Approx.18 305 155 HRL200-A-40 Approx.35 590 295 HRL300-A-40 Approx.45 760 380 3.2 Installation HRL Series 3-6