Determining Tap Water Concentrations from Water Report

Hey guys,

Wondering if you can help me clarify/confirm that I am reading my City's water quality report correctly in order to determine the concentrations of ions in the tap water I'm using for brewing. So far I have yet to focus on any aspect of my water chemistry, but I'm looking to expand the influence over my beers.

The last water quality report published online is from 2016 - http://www.longbeachny.gov/vertical...016_Drinking_Water_Quality_Report_-_Final.pdf. I've seen the 2017 report at the library and the concentrations are almost identical.

I've been reviewing Palmer's reference: http://howtobrew.com/book/section-3/understanding-the-mash-ph/reading-a-water-report

Now please bear with me as I have not used chemistry outside of my experiments with eutrophication (nitrogen, nitrogen sulfide) for quite a few years. Basically, mg/L should be 1:1 with ppm, but I know its not always the case depending on the atomic weight of an element/compound. I'm looking for help/confirmation on converting the concentrations of elements/compounds from mg/L to ppm.

Based on my City's water quality report:

Calcium - Max reading: 13.1 mg/L - Average reading: 7 mg/L
Magnesium - Max reading: 1.3 mg/L ; Average reading: 1 mg/L
Sodium - Max reading: 10.4 mg/L - Average reading: 5.2 mg/L
Chloride - Max reading: 6.9 mg/L - Average reading: 3.45 mg/L
Sulfate - Max reading: 201 mg/L - Average reading: 100.5 mg/L
Bicarbonate - Did not find this reading; maybe I overlooked it? Not sure how to calculate this based on the water report.

If I convert the readings above at a 1:1 ratio from mg/L to ppm, I observe the following:

Calcium - Max: 13.1 ppm; Average: 7 ppm
Magnesium - Max: 1.3 ppm; Average - 1 ppm
Sodium - Max: 10.4 ppm; Average - 5.2 ppm
Chloride - Max: 6.9 ppm; Average - 3.45 ppm
Sulfate - Max: 201 ppm; Average - 100.5 ppm

When compared the following concentrations found on the Palmer reference, some elements (Sodium, Chloride, Sulfate) fall within the listed range below. Others (Calcium, Magnesium) fall largely short of the range.

Calcium - 50-150 ppm
Magnesium - 10-30 ppm
Sodium - 0-150 ppm
Chloride - 0-250 ppm
Sulfate - 50-150 ppm normal bitter beers; 150-350 ppm for very bitter beers
Bicarbonate - Varies based on type of malts used in the grist

Should I be multiplying the concentration of mg/L by the equivalent weight listed on the Palmer reference to get ppm? When I do this, I observe the following:

Calcium - Max: 262 ppm; Average: 140 ppm (Equivalent weight 20.0)
Magnesium - Max: 15.73 ppm; Average - 12.1 ppm (Equivalent weight 12.1)
Sodium - Max: 238.16 ppm; Average - 119.08 ppm (Equivalent weight 22.9)
Chloride - Max: 224.26 ppm; Average - 122.13 ppm (Equivalent weight 35.4)
Sulfate - Max: 9648 ppm; Average - 4824 ppm (Equivalent weight 48.0)

Obviously, some of the readings in ppm would be utterly extreme (Sulfate), so I am definitely leaning more towards the 1:1 conversion than calculating by multiplying by the equivalent weight.

Either that or I am completely off-base and am doing the complete wrong calculations.

All and any help will be appreciated! Thanks guys, cheers.

 

Perfect. That is what I was hoping for.

Yea that's especially true in the area I live, considering we get our water from a deep aquifer and seasonal changes in the aquifer can alter the % composition of elements/compounds found in the water.

Especially here. Our water infrastructure is 80+ years old and is unfortunately failing. We have a ton of iron in our water that is a result of pipe corrosion and "hydrant flushing". It is not uncommon to get brown water out of our faucets in the morning when the pipes have been dormant for a few hours. The residents are at the city council meeting every month yelling about the brown water (iron) so their main concern is making sure the water is clean and healthy to drink.

I will reach out to the City to request the Alkalinity.

 

Forgot to include this above:

Would you guys agree that the water composition should be considered as "hard". My calculations show (based on the max concentration of Ca) that the max Ca concentration in a 5 gallon batch of beer would be 247.94 ppm (13.1 ppm x 18.9271 Liters (5 gallons)).

This reading is well above the concentrations listed on Palmer's reference (50-150 ppm). Would my best bet to lower the concentration of Ca would be to use distilled water for my batches of beer at a ratio of 1:1 to tap water?

 

I just calculated the composition (low, mean, high) of Calcium, Magnesium, Sodium, Chloride and Sulfate below based on a calculation of xx ppm x 18.9271 Liters for a standard 5 gallon batch:

Calcium Low: 17.03 Mean: 132.49 High: 247.95
Magneisum Low: 13.25 Mean: 18.93 High: 24.61
Sodium Low: 0 Mean: 98.42 High: 196.84
Chloride Low: 0 Mean: 62.30 High: 130.60
Sulfate Low: 0 Mean: 1902.17 High: 3804.35

The sulfate levels are extremely alarming!

 

I'm definitely starting to lean towards this as the iron issue is not linear and can pop up at anytime. Also, the sulfate levels are extremely high.

Yes. I was trying to avoid using RO or Distilled water for economic purposes, but I'd rather my beer taste better and know what was going into it than continue to "guess" and play it by ear.

This thread has been extremely helpful. Thanks guys!

 

Just to clarify, the City is Long Beach, NY, not Cali. It gets confused a lot, even from people on Long Island who have no idea Long Beach exists. So you are probably a little more familiar with the type of water.

I will find out the manganese concentrations as well.