Mix your own fertilizers

Fertilizer: Calculate a nutrient recipe

By Boston Public Library, licensed CC BY 2.0

Now that you have the two basic equations for the production of nutrient solutions, we want to use them to calculate the amounts of fertilizer required for a nutrient solution recipe.

If you are not familiar with the two equations, read this first: Hydroponic systems: Calculating the concentrations of nutrient solutions using the two equations.

Here is our problem: We want to use a modified Sonneveld solution (Matson and Peters, Insidegrower) for herbs in an NFT system. We use two 5-gallon containers and injectors set to a concentration of 100: 1 and call them storage tank A and storage tank B. How much of each fertilizer do we have to put in each storage tank ?

You may be asking: why two storage tanks? This is due to the fact that certain chemicals in our fertilizer solution react with each other as soon as they come into contact with each other. In all nutrient solutions ( fertilizer mixtures ) you have calcium, phosphates and sulfates - among other things, these three chemicals for all plants vital are. The last two react with calcium and are no longer present in the form we need in our nutrient solution. They connect to each other and fall to the bottom of the container as white flakes ( precipitates ). Therefore, phosphates and sulfates must be kept separate from calcium and, when introduced into the nutrient solution of the ( system, saved from direct mixing by means of a dosing pump or measuring cup ).

Modified Sonneveld recipe for herbs

element	concentration
nitrogen	150 ppm
phosphorus	31 ppm
potassium	210 ppm
calcium	90 ppm
magnesium	24 ppm
iron	1 ppm
manganese	0.25 ppm
zinc	0.13 ppm
copper	0.023 ppm
Molybdenum	0.024 ppm
boron	0.16 ppm

These are the fertilizers that we will use. Some fertilizers contain more than one nutrient in the recipe, while others contain only one. Here is a small overview Commercial fertilizer from which you can put together your recipe

Fertilizer	Contained nutrients (Nitrogen phosphate potassium and other nutrients)
Calcium nitrate	15.5-0-0, 19% Ca (calcium)
Ammonium nitrate	34-0-0
Potassium nitrate	13-0-44
Potassium phosphate monobasic	0-52-34
Magnesium sulfate	9.1% mg (magnesium)
Sequestrene 330 ^TM	10% Fe (iron)
Manganese sulfate	31% Mn (Mangan)
Zinc sulfate	35.5% Zn (zinc)
Copper sulfate	25% Cu (copper)
Boron	11% B (Boron)
Sodium molybdenum	39% Mo (molybdenum)

The first thing you notice is that we have three sources of nitrogen (calcium nitrate, ammonium nitrate and potassium nitrate), have two sources of potassium (potassium nitrate and potassium phosphate monobasic) and one source of calcium (calcium nitrate) and phosphorus (single-base potassium phosphate). We can start calculating the calcium or phosphorus in the recipe because only one fertilizer provides each nutrient. Let's start with calcium.

The recipe provides 90 ppm calcium. We calculate how much calcium nitrate we need to use to achieve this by using the first of our two equations.

Duenger Mischung 1

We need to add 895.3 g calcium nitrate to get 90 ppm calcium. However, calcium nitrate also contains nitrogen. We use the second equation to determine how much nitrogen should be added in ppm.

Duenger Mischung 2

We add 73.4 mg N / l or 73.4 ppm nitrogen. Our recipe provides 150 ppm nitrogen. If we subtract 73.4 ppm nitrogen from it, we have to add 76.6 ppm nitrogen.

Let us now calculate how much single-base potassium phosphate we have to use to deliver 31 ppm phosphorus.

Duenger Mischung 3

We need to add 262 g of potassium phosphate monobed to get 31 ppm phosphorus. However, potassium phosphate also contains single-base potassium. We use the second equation to determine how much potassium should be added in ppm.

Duenger Mischung 4

We add 39 mg K / l or 39 ppm potassium. Our recipe provides 210 ppm potassium. If we subtract 39 ppm of potassium from it, we see that we still have to add 171 ppm of potassium.

We have only one other source of potassium, namely potassium nitrate. Let's calculate how much we have to use of it.

Duenger Mischung 5

We need to add 885 g of potassium nitrate to get 171 ppm of potassium. However, potassium nitrate also contains nitrogen. We use the second equation to determine how much nitrogen should be added in ppm.

Duenger Mischung 6

We add 61 mg N / l or 61 ppm nitrogen. Our recipe provides 150 ppm nitrogen. We supplied 73.4 ppm nitrogen from calcium nitrate and had to add 76.6 ppm nitrogen. Now we can subtract 61 ppm nitrogen. We still have to add 15.6 ppm nitrogen. The only source of nitrogen that we have is ammonium nitrate.

Let us now calculate how much ammonium nitrate we have to use to deliver 15.6 ppm nitrogen.

Duenger Mischung 7

We need to add 86.7 g of ammonium nitrate to get 15.6 ppm nitrogen.

At this point we have completed the nitrogen, phosphorus, potassium and calcium part of the recipe. For the other nutrients, we only need to use the first equation, since the fertilizers that we use for their supply contain only one nutrient in the recipe.

Duenger Mischung 8

We need to add 498.5 grams of magnesium sulfate to get 24 ppm magnesium.

Duenger Mischung 9 We need to add 18.9 grams of Sequestren 330 to get 1 ppm of iron.

Duenger Mischung 10

We need to add 1.5 grams of manganese sulfate to get 0.25 ppm manganese.

It is easier to weigh small amounts of fertilizers in milligrams. The conversion from milligrams to grams is therefore carried out as follows

Duenger Mischung 11

We need to add 692 milligrams of zinc sulfate to get 0.13 ppm zinc.

Duenger Mischung 12

We need to add 0.17 milligrams of copper sulfate to get 0.023 ppm copper.

Duenger Mischung 13

We need to add 2.8 milligrams of borax to get 0.16 ppm borax.

Duenger Mischung 14

We need to add 0.12 milligrams of sodium molybdate to get 0.024 ppm molybdenum.

Summary:

Element	Addition	Nutrient Solution
Calcium	895.3 g calcium nitrate	90 ppm calcium
Phosphorus	262 g of potassium phosphate monobasic	31 ppm phosphorus
Potassium	885 g potassium nitrate	171 ppm potassium
Nitrogen	86.7 g ammonium nitrate	15.6 ppm nitrogen
Magnesium	498.5 grams of magnesium sulfate	24 ppm magnesium
Iron	18.9 grams of sequestrene 330	1 ppm iron
Manganese	1.5 grams of manganese sulfate	0.25 ppm manganese
Zinc	692 milligrams of zinc sulfate	0.13 ppm zinc
Copper	0.17 milligrams of copper sulfate	0.023 ppm copper
Boron	2.8 milligrams of borax	0.16 ppm boron
Molybdenum	0.12 milligrams of sodium molybdate	0.024 ppm molybdenum

Now all calculations have been completed. Now we have to decide in which storage tank, A or B, we give the individual fertilizers. In general, the calcium should be kept in a tank other than the sulfates and phosphates, as they can form precipitates that can clog the drip bodies of the irrigation system. Using this guideline, we can put the calcium nitrate in one tank and the monobasic potassium phosphate, magnesium sulfate, manganese sulfate, zinc sulfate and copper sulfate in the other tank. The rest of the fertilizers can be placed in both tanks.

You should also consider the amount of nutrients in irrigation water. For example, if we use irrigation water that contains 10 ppm magnesium, we only need to add 14 ppm more with our fertilizer (24 ppm Mg, which are required in the recipe, minus 10 ppm Mg in water). This is a great way to use nutrients more efficiently and fine-tune your fertilizer plan.

With some micronutrients, you have to decide for yourself what you want to add. You could do a small experiment to find out whether you need to add 0.12 milligrams of sodium molybdate to your stock solution, for example, or whether you are satisfied with the performance of your plants without this addition.

One last point to consider. Sometimes the calculations don't work as well as here for fertilizers that contain more than one required nutrient, and you may need to add more of a nutrient, than is provided in the recipe to provide the other nutrient.

For example, if you apply calcium nitrate to meet calcium needs, the solution may not contain enough nitrogen. In such cases, you have to decide which nutrient you want to give priority to. For example, you could apply calcium nitrate to meet the plants' nitrogen needs because the excess amount of calcium does not harm the plants. Or you choose to apply it based on the plant's calcium needs because the lack of nitrogen is just a few ppm.

Here you will find what problems there may be with a lack and excess of fertilizer

At this point we can give you recommendations for your plantations with modern analysis technology. Contact us...

Context:

ID: 417

pH and Ec Finder

john deere California Agricultural Museum pd s

Here you can view the plants that have similar pH and Ec values and can therefore, at least in this respect, be planted together in an aqua or hydroponic system. Also pay attention to the temperature.

What are the nutrient requirements for certain plants? This list shows the nutrient concentration preferred by each plant. Note the differences within the subspecies/breeding . Please remember: there are 23,000 varieties of tomatoes - of course these vary in terms of preferred temperatures as well as Ec and pH values! The fine-tuning of the nutrient composition is not even mentioned here. More details about the list at the end of the same.

You can also download the list of pH and Ec values here. This list should only serve as an orientation and does not save you from a detailed check of your cultivation. Don't forget that even within the same subspecies the differences can be very big. And of course we do not take any responsibility for the information given. We also offer a precise determination of the nutrient requirements for your plants and can thus provide you with a nutrient roadmap.

Download as: CSV, XLSX, ODS, Text, PDF

The Ec value

We measure the salt concentration with an Ec, TDS or PPM measuring device. The nutrients dissolve in the water and provide a value measured by the EC or PPM measuring device that shows you how much fertilizer is contained in the nutrient liquid and therefore how much fertilizer needs to be added if necessary.

As soon as the Ec value drops, you need to fertilize accordingly. You can measure, check and control this every minute with one of our systems or by hand with an Ec pH measuring device . The advantage of the control system is obvious: with minimal steps in the supply of the nutrient solution through a micropump, you can always maintain the exact range that is optimal for the plant.

If the Ec value increases, you simply need to add more water to the nutrient solution. A rising Ec value can have many reasons: contamination from the plants themselves, water that is too rich in minerals, accidental overdose, etc.

The pH value

If the pH value falls below the recommended value (towards acidic / pH 1), you can use a basic solution to correct the pH value back towards basic (pH 14).

If the pH value rises above the recommended value (towards basic / pH 14), you can correct the pH value back towards acidic (pH 1) with an acidic solution. You can measure, check and control this every minute with one of our systems - but we have already mentioned that.

According to the old school wisdom: Acid + alkali equals salt + water, you can use anything from household vinegar (acid) to baking soda/soda (base) to correct the pH in one direction or the other. But: as mentioned, salts are formed. These of course change the Ec value. At this point in the process you have to observe the plants closely in order to detect any deficiency symptoms in good time.

If you only have 50 or 100 plants, a complete replacement of the nutrient solution is always the safe way. As a guide: 100 tomato plants consume around 5 liters of fertilizer concentrate in three months in an outdoor area with around 150 liters of water/nutrient solution (central Portugal, mid-summer). In large systems, it is preferred to analyze the current nutrient solution in order to simply supplement the missing components in a targeted manner.

The pH and electrical conductivity values ( Ec, TDM, PPM values) given here are guidelines only. Your specific requirements for plant cultivation vary depending on the subspecies of the plant, growth phase and many other factors (UV value, brightness, lighting duration, genus/breeding/subspecies, temperature, etc.). For hydroponics use inorganic fertilizer, for soil use organic. The organic fertilizer requires microorganisms to break down the nutrients. These microorganisms are missing in hydroponics.

The values mentioned here are only for hydroponic plants (ground plants sometimes differ greatly). Almost all plants tolerate slight over or under concentrations in soil. The plant “consumes” different amounts of the individual substances (nutrients). If the nutrient solution is not optimally composed, deficiency symptoms can quickly occur. With general nutrient solutions or fertilizer mixtures, the entire nutrient solution usually needs to be replaced every three to four weeks. An analysis of these small quantities is in any case more expensive than the amount of fertilizer you pay instead.

The temperature

Temperature greatly influences the Ec and pH of the nutrient solution. Most pH meters therefore have automatic temperature compensation. Some EC and pH meters come with a bag containing a calibration liquid that can be used to calibrate the meter. Depending on the quality of the sensors used, this should be done every few weeks. We strongly recommend that hobbyists join one or more hydroponic community forums.

Below are some articles to further delve into the subject...