731: From system2: To vacuum pump3: Moisture condenses on cold surfaces4: Mixture of dry ice and methyl alcoholFig 41 – dehydration cold trapPerform dehydration as follows:1. Connect a high capacity vacuum pump (0.002 m3/s or larger is recommended) to the refrigerant vacuum/charging valve. Tubing from the pump to the chiller should be as short in length with a minimum diameter of 13mm and as large in diameter as possible to provide least resistance to gas flow.2. Use an absolute pressure manometer or a electronic micron gage to measure the vacuum. Open the shutoffvalve to the vacuum indicator only when taking a reading. Leave the valve open for 3 minutes to allow theindicator vacuum to equalize with the chiller vacuum.3. If the entire chiller is to be dehydrated, open all isolation valves (if present).4. With the chiller ambient temperature at 15.6°C or higher, operate the vacuum pump until the manometer reads757 mm Hg (vac), (-100.9 kPag), or a vacuum indicator reads 1.7°C. Operate the pump an additional 2 hours. Donot apply a greater vacuum than 100.1 kPa (757 mm Hg) or go below 0.56°C on the wet bulb vacuum indicator.At this temperature and pressure, isolated pockets of moisture can turn into ice. The slow rate of evaporation(sublimation) of ice at these low temperatures and pressures greatly increases dehydration time.5. Valve off the vacuum pump, stop the pump, and record the instrument reading.6. After a 2-hour wait, take another instrument reading. If the reading has not changed, dehydration is complete. Ifthe reading indicates vacuum loss, repeat Steps 4 and 5.7. If the reading continues to change after several attempts, perform a leak test (maximum 310 kPa pressure).Locate and repair the leak, and repeat dehydration.8. Once dehydration is complete, the evacuation process can continue. The final vacuum prior to charging the unitwith refrigerant should in all cases be 0.3 kPa [abs] or less.5.1.9- Inspect water pipingRefer to piping diagrams provided in the certified drawings, Inspect the piping to the cooler and condenser. Besure that flow directions are correct and that all piping specifications have been met. Check the tightening ofwaterboxes mounting. Check if there’s no water leak between tube-sheet and waterbox. Do not introduce anysignificant static or dynamic pressure into the heat exchange circuit (with regard to the design operatingpressures).Before any start-up verify that the heat exchange fluid is compatible with the materials and the water circuitcoating. In case additives or other fluids than those recommended by Carrier are used, ensure that the fluids arenot considered as a gas, and that they belong to class 2, as defined in directive 97/23/EC.Carrier recommendations on heat exchange fluids:• No NH4+ ammonium ions in the water, they are very detrimental for copper. This is one of the most importantfactors for the operating life of copper piping. A content of several tenths of mg/l will badly corrode the copper overtime.• Cl- Chloride ions are detrimental for copper with a risk of perforations by corrosion by puncture. If possiblekeep below 10 mg/l.• SO4 2- sulphate ions can cause perforating corrosion, if their content is above 30 mg/l.No fluoride ions (<0.1 mg/l).• No Fe2+ and Fe3+ ions with non negligible levels of dissolved oxygen must be present. Dissolved iron < 5 mg/lwith dissolved oxygen < 5 mg/l.• Dissolved silica: Silica is an acid element of water and can also lead to corrosion risks. Content < 1mg/l.