Open loop ground water systems, Water quality – WaterFurnace Envisio Series Console User Manual

17

ENVISION CONSOLE INSTALLATION MANUAL

Open Loop Ground Water Systems

Always maintain water pressure in the heat exchanger by placing water control valves at the outlet of the unit to prevent

mineral precipitation. Use a closed, bladder-type expansion tank to minimize mineral formation due to air exposure. Insure

proper water flow through the unit by checking pressure drop across the heat exchanger and comparing it to the figures in

unit capacity data tables in the specification catalog. 1.5-2 GPM of flow per ton of cooling capacity is recommended in open

loop applications.

Discharge water from the unit is not contaminated in any manner and can be disposed of in various ways, depending on

local codes, i.e. recharge well, storm sewer, drain field, adjacent stream or pond, etc. Most local codes forbid the use of

sanitary sewer for disposal. Consult your local building and zoning departments to assure compliance in your area.

Note: For open loop/groundwater systems or systems that do not contain an antifreeze solution, set SW1-Switch #2 to the

“WELL” position

(Refer to the Dip Switch Field Selection table). Slow opening/closing solenoid valves (type VM) are recom-

mended to eliminate water hammer.

Water Quality

In ground water situations where scaling could be heavy or where biological growth such as iron bacteria will be present,

a closed loop system is recommended. The heat exchanger coils in ground water systems may, over a period of time, lose

heat exchange capabilities due to a buildup of mineral deposits inside. These can be cleaned, but only by a qualified service

mechanic, as special solutions and pumping equipment are required. Desuperheater coils can likewise become scaled and

possibly plugged. In areas with extremely hard water, the owner should be informed that the heat exchanger may require

occasional flushing.

Units with cupronickel heat exchangers are recommended for open loop applications due to the increased resistance to

build-up and corrosion, along with reduced wear caused by acid cleaning.

Material

Copper

90/10 Cupronickel

316 Stainless Steel

pH

Acidity/Alkalinity

7 - 9

7 - 9

7 - 9

Scaling

Calcium and

Magnesium Carbonate

(Total Hardness)

less than 350 ppm

(Total Hardness)

less than 350 ppm

(Total Hardness)

less than 350 ppm

Corrosion

Hydrogen Sulfide

Less than 0.5 ppm (rotten egg

smell appears at 0.5 ppm)

10 - 50 ppm

Less than 1 ppm

Sulfates

Less than 125 ppm

Less than 125 ppm

Less than 200 ppm

Chlorine

Less than 0.5 ppm

Less than 0.5 ppm

Less than 0.5 ppm

Chlorides

Less than 20 ppm

Less than 125 ppm

Less than 300 ppm

Carbon Dioxide

Less than 50 ppm

10 - 50 ppm

10 - 50 ppm

Ammonia

Less than 2 ppm

Less than 2 ppm

Less than 20 ppm

Ammonia Chloride

Less than 0.5 ppm

Less than 0.5 ppm

Less than 0.5 ppm

Ammonia Nitrate

Less than 0.5 ppm

Less than 0.5 ppm

Less than 0.5 ppm

Ammonia Hydroxide

Less than 0.5 ppm

Less than 0.5 ppm

Less than 0.5 ppm

Ammonia Sulfate

Less than 0.5 ppm

Less than 0.5 ppm

Less than 0.5 ppm

Total Dissolved Solids (TDS)

Less than 1000 ppm

1000 - 1500 ppm

1000 - 1500 ppm

LSI Index

+0.5 to -0.5

+0.5 to -0.5

+0.5 to -0.5

Iron Fouling

(Biological Growth)

Iron, FE

2

+ (Ferrous)

Bacterial Iron Potential

< 0.2 ppm

< 0.2 ppm

< 0.2 ppm

Iron Oxide

Less than 1 ppm, above this

level deposition will occur

Less than 1 ppm, above this

level deposition will occur

Less than 1 ppm, above this

level deposition will occur

Erosion

Suspended Solids

Less than 10 ppm and filtered

for max. of 600 micron size

Less than 10 ppm and filtered

for max. of 600 micron size

Less than 10 ppm and filtered

for max. of 600 micron size

Threshold Velocity

(Fresh Water)

< 6 ft/sec

< 6 ft/sec

< 6 ft/sec

NOTES: Grains = ppm divided by 17

mg/L is equivalent to ppm

2/22/12