Nutrient Solution Formulation for Hydroponic Perlite Rockwool NFT

Discussion in 'First Time Marijuana Growers' started by knr117, Oct 3, 2010.

  1. Below is a complete list of the formulas the university of Florida came up with for hydro tomatoes.

    many feel tomatoes are the same as MJ. I personally feel there are some major differences but that is just my view. The info is very techno heavy but there are more than a few members here that I know of that may understand this info.
    For others it's a good read if your interested in how nutrients work and amounts to use.

    With that said it may even be posted here already. If so someone PM me and I'll delete the thread.
     
  2. George J. Hochmuth and Robert C. Hochmuth2
    1. This document is HS796, one of a series of the Department of Horticultural Sciences, Florida Cooperative Extension Service, Institute of Food and
    Agricultural Sciences, University of Florida. Publication date: October, 1990 as SSVEC44. Revision date: August 2001. Reviewed November 2008. Please
    visit the EDIS Web site at EDIS - Electronic Data Information Source - UF/IFAS Extension.
    2. George J. Hochmuth, associate dean for research and associate director, Florida Agricultural Experiment Station, Robert C. Hochmuth, agent IV, North
    Florida Research and Education Center - Suwannee Valley, Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of
    Florida, Gainesville, 32611.
    The Institute of Food and Agricultural Sciences (IFAS) is an Equal Opportunity Institution authorized to provide research, educational information and
    other services only to individuals and institutions that function with non-discrimination with respect to race, creed, color, religion, age, disability, sex,
    sexual orientation, marital status, national origin, political opinions or affiliations. U.S. Department of Agriculture, Cooperative Extension Service,
    University of Florida, IFAS, Florida A. & M. University Cooperative Extension Program, and Boards of County Commissioners Cooperating. Larry
    Arrington, Dean
    Plants require 16 elements for growth and these
    nutrients can be supplied from air, water, and
    fertilizers. The 16 elements are carbon (C), hydrogen
    (H), oxygen (O), phosphorus (P), potassium (K),
    nitrogen (N), sulfur (S), calcium (Ca), iron (Fe),
    magnesium (Mg), boron (B), manganese (Mn),
    copper (Cu), zinc (Zn), molybdenum (Mo), and
    chlorine (Cl). The key to successful management of a
    fertilizer program is to ensure adequate
    concentrations of all nutrients throughout the life
    cycle of the crop. Inadequate or excessive amounts
    of any nutrient result in poor crop performance.
    Excessive amounts can be especially troublesome
    since they can damage the crop, waste money and
    fertilizer resources, and pollute the environment when
    fertilizer is released during flushing of the nutrient
    delivery system.
    For Florida greenhouse vegetable producers,
    management focuses on all nutrients except for C, H,
    and O. The latter three elements are usually supplied
    in adequate amounts from air and water. Growers in
    northern climates, where greenhouses are not
    ventilated in the winter, see benefits from additions of
    C from carbon dioxide (CO2). Increased yields in
    Florida from additions of CO2 are unlikely due to the
    need for frequent ventilation.
    Crop demand for nutrients changes through the
    season. Small amounts of nutrients are needed early,
    then the demand increases as the crop grows,
    especially after several clusters of fruit have been set
    on the plant. A common problem comes early in the
    season when plants become too vegetative (bullish)
    from too much N. The bullish growth distorts the
    leaves and stems, causing cracks and grooves in the
    stems. These openings are excellent entry ports for
    decay-causing organisms such as soft rot. Bullish
    plants usually produce misshapen fruits often with
    significant amounts of blossom-end rot and
    cat-facing. Keeping the N level low (60 to 70 parts
    per million) early in the season helps eliminate
    bullishness.
    High K also can be a problem since it can
    interfere with the plant's capability to absorb Ca and
    Mg. Plants exposed to excess K often develop Mg
    deficiency on the lower leaves and the fruits often
    develop blossom-end rot (BER), especially early in
    the season.

    _____________________________________________________________________

    Nutrient management programs should begin
    with an understanding of the nutrient solution
    concentrations in parts per million (ppm) for the
    various nutrients required by tomato plants. By
    managing the concentrations of individual nutrients,
    growers can control the growth and yield of the crop.
    Table 1 presents the fertilizer recommendations for
    tomatoes for the various growth stages during the
    season in Florida. These recommendations are
    applicable to all types of production systems (perlite,
    rockwool, and NFT) in which healthy roots are
    maintained, and are a suitable base when determining
    a nutrient solution plan for cucumbers and peppers.
    However, cucumbers will need more N early in the
    season than tomato.
    The major elements to manage are N and K for
    the reasons cited above. The program outlined in
    Table 1 has been proven in Florida and should
    provide adequate nutrition and avoid the problems of
    bullishness as well as the problems of fruit ripening
    disorders indirectly caused by excess K. Final
    solution pH should be in the range of 5.8 to 6.2.
    One of the first steps in a nutrient management
    program is to test the well water. A water sample
    should be analyzed for pH, carbonates, S, Mg, Ca, and
    Fe. Most well water in Florida has pH greater than
    6.5. The pH and carbonates are used to guide in the
    acidification of the nutrient solution. Water from
    many wells in Florida contains significant amounts of
    Ca and often small amounts of Mg. Growers can take
    advantage of these nutrients, which in the case of Ca,
    might be 40 to 60 ppm. Some, but probably not all of
    this Ca is available to the crop.
    Sulfur and iron concentrations are determined
    because they can increase potential for irrigation
    emitter clogging from bacterial slimes that use the Fe
    and S for growth. These nutrients generally are not
    considered in the nutrient formulation calculations.
    Formulation Methods
    There are basically two methods to supply the
    fertilizer nutrients to the crop: 1) premixed products,
    or 2) grower-formulated solutions. The two methods
    differ in the approach to formulating the fertilizer and
    the resulting nutrient-use efficiency. Fertilizer
    materials that can be used for both methods are

    presented in Table 2. The formula in this publication
    are for a final dilution of 1 gallon each stock to 100
    gallons of final solution. If using proportionals
    installed in parallel on one water source line, amounts
    of fertilizers in stocks will need to be calculated
    keeping in mind the intended final concentrations.
    Pre-Mix Method
    There are several commercial pre-mixed
    fertilizer formulations and some of these generalized
    formulations are presented in Table 2. Some of these
    materials contain Mg, some do not. Those that do not
    will need to be supplemented with magnesium
    sulfate. All formulations need supplementing with
    Ca (from calcium nitrate or calcium chloride) and N
    (from several possible sources). Formulations using
    these premixed materials that approximate the
    recommended program are presented in Table 3. In
    Table 3, the amount of pre-mixed material was
    chosen to provide adequate P since the pre-mixed
    material is the only source of P. The pre-mixed
    materials contain large amounts of K making it
    difficult to achieve the desired K and Ca
    concentrations. This could cause an early problem
    with BER when there is excess K coming from the A
    stock and a low Ca concentration in the well water
    (below 50 ppm) because K can interfere with Ca
    uptake by the root. This problem is common to all
    pre-mixed formula. More Ca can be supplied from
    calcium chloride but it would be better to have lower
    K concentrations. A related problem is that some of
    the pre-mixed formula have too much N in the
    formulation to allow for providing adequate Ca by
    adding calcium nitrate. An option to increase the Ca
    in the solution is to supplement the calcium nitrate
    stock with calcium chloride. Each pound of calcium
    chloride (36% Ca) in 30 gallons of stock solution
    results in a 14 ppm increase in Ca in the final nutrient
    solution delivered to the plants. The pre-mixed
    materials come fairly close to providing the desired
    concentrations of micronutrients, although some are
    higher than needed in Florida.
    Formulation Recipe Method
    Information on formulating fertilizer solutions
    from individual ingredients is presented in Tables 4
    and 5. Four formula are presented to provide
    options for formulating nutrient solutions depending
    on grower preference. Formula 1 uses phosphoric
    acid to provide P and to simultaneously partially
    acidify the nutrient solution. Additional acidification
    might be required for some water and this can be
    accomplished with sulfuric acid. This formula also
    uses potassium chloride to provide K. There is no
    problem with using potassium chloride as a partial
    source of K. It provides K in the same form as
    potassium nitrate and potassium chloride is less
    expensive. The chloride ion is not toxic to plants in
    these amounts provided and some research shows that
    it contributes to fewer fruits with soft rot. Only
    greenhouse soluble-grade potassium chloride should
    be used. Formula 1 also uses individual chemicals to
    provide the micronutrients.
    Formula 2 is a variation of formula 1, however,
    formula 2 uses a pre-mixed micronutrient package,
    S.T.E.M. (soluble trace element mixture), to supply
    most of the micronutrients. However, S.T.E.M. does
    not, alone, provide enough B, Fe, or Mo, so these are
    supplemented from individual ingredients.
    Formula 3 uses monopotassium phosphate to
    provide the P and some K. Monopotassium
    phosphate is the most common source of P in the
    commercial pre-mixed materials. Acidification of the
    nutrient solution should be accomplished by another
    acid such as sulfuric acid. Formula 3 also uses
    potassium chloride and provides the micronutrients
    from individual ingredients.
    Formula 4 uses potassium nitrate to supply all of
    the K. One potential problem in this formula is that
    large amounts of N are also supplied with the
    potassium nitrate and this restricts the amounts of
    calcium nitrate that can be added. Reducing the
    calcium nitrate too far might lead to BER unless the
    well water is supplying some Ca. Supplying some of
    the K from potassium chloride will allow room for
    more calcium nitrate.
    Products for the formula method are easily
    obtainable in Florida and this method should result in
    considerable financial savings, especially for large
    growers. There is a small amount of extra effort
    involved in the formula method due to the extra
    measuring. The resulting higher degree of control
    over the nutrient supply to the crop should more than
    pay back any increased effort.
    Water-Fertilization Relationship
    The nutrient solution formulations presented in
    this publication were designed for production systems
    using hydroponic approaches to tomato culture. The
    media discussed in this publication (perlite, rockwool
    or NFT) require frequent irrigations during the day,
    ranging from 10 to 20 cycles per day, depending on
    the weather and greenhouse environment, in order to
    maintain about 20% solution leach. It is impossible
    to have an exact formulation that will work for every
    production system under any environmental
    conditions. For example, when using a media of high
    water-holding capacity, fewer irrigation cycles will be
    needed during the day. In this situation, the nutrient
    concentrations in the irrigation water might need to
    be greater than those presented in this publication so
    that adequate nutrition is supplied. A general
    rule-of-thumb is that nutrient concentrations need to
    be greater in production systems requiring fewer
    irritations, compared to systems requiring more
    frequent irritations
     
  3. <<<<<<<<<<<<<<<<<<<<Tables Come next>>>>>>>>>>>>>>

    Table 1. Fertilizer recommendations for hydroponic (perlite, rockwool, and NFT) tomatoes in Florida.
    Stage of growth
    1 2 3 4 5
    Nutrient
    Transplant to
    1st cluster
    1st cluster to
    2nd cluster
    2nd cluster to
    3rd cluster
    3rd cluster to
    5th cluster
    5th cluster to
    termination
    --------------- Final delivered nutrient solution concentration (ppm)z --------------
    N 70 80 100 120 150
    P 50 50 50 50 50
    K 120 120 150 150 200
    Ca 150 150 150 150 150
    Mg 40 40 40 50 50
    S 50 50 50 60 60
    Fe 2.8 2.8 2.8 2.8 2.8
    Cu 0.2 0.2 0.2 0.2 0.2
    Mn 0.8 0.8 0.8 0.8 0.8
    Zn 0.3 0.3 0.3 0.3 0.3
    B 0.7 0.7 0.7 0.7 0.7
    Mo 0.05 0.05 0.05 0.05 0.05
    NOTE: Ca, Mg, and S concentrations may vary depending on Ca and Mg concentration in wellwater and amount of
    sulfuric acid used for acidification.
    z 1ppm = 1mg/liter
    _______________________________________________________________________

    Table 2. Pre-mixed and individual-salt fertilizer materials for use in hydroponic nutrient solution formulations.
    Selected Pre-mixed Materialsz
    Nutrient Pre-mix 1
    4-18-38
    %
    Pre-mix 2
    3-15-27
    %
    Pre-mix 3
    5-11-26
    %
    Pre-mix 4
    7-17-37
    %
    N 4 3 5 7
    P
    2
    O
    5
    (P) 18 (7.7) 15 (6.5) 11 (4.7) 17 (7.3)
    K
    2
    O (K) 38 (32) 27 (22) 26 (22) 37 (31)
    Mg 0 5.32 0 0
    Fe 0.4 0.45 0.31 0.40
    Mn 0.2 0.057 0.05 0.10
    Zn 0.05 0.034 0.016 0.02
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 5
    Table 2. Pre-mixed and individual-salt fertilizer materials for use in hydroponic nutrient solution formulations.
    Cu 0.05 0.011 0.016 0.01
    B 0.20 0.170 0.05 0.18
    Mo 0.01 0.011 0.01 0.01
    Individual Ingredientsy
    Ammonium nitrate (NH
    4
    NO
    3
    ) 33.5% N
    Calcium nitrate liquid (7-0-0-11) 12.1 lb/gal (Ca(NO
    3
    )
    2
    ) 7%N, 11% Ca
    Calcium nitrate (Ca(NO
    3
    )
    2
    )-dry 15% N, 19% Ca
    Calcium chloride (CaCl
    2
    ) 36% Ca
    Potassium nitrate (KNO
    3
    ) 13% N, 36.5 K
    Monopotassium phosphate (KH
    2
    PO
    4
    ) 23% P, 28% K
    Phosphoric acid (H
    3
    PO
    4
    ) 13 lb./gal. 23% P
    Potassium chloride (KCl) - greenhouse 51% K
    Magnesium sulfate (MgSO
    4
    ) 10% Mg, 14% S
    Solubor 20.5% B
    Copper sulfate (CuSO
    4
    ) 25% Cu
    Zinc sulfate (ZnSO
    4
    ) 36% Zn
    Iron, Fe 330 chelated iron, etc. 10% Fe
    Manganous sulfate (MnSO
    4
    ) 28% Mn
    Sodium molybdate (Na
    2
    (Mo)
    4
    ) (liquid), (11.4 lb/gal) 17% Mo
    Sodium molybdate (dry) Na
    2
    (MoO
    4
    ) 39.6 % Mo
    Soluble Trace Element Mixture (S.T.E.M.): 1.35% B
    7.5% Fe
    8.0% Mn
    0.04% Mo
    4.5% Zn
    3.2 % Cu
    Convert K
    2
    O to K by multiplying by 0.83. Convert P
    2
    O
    5
    to P by multiplying by 0.44.
    z Mention of a trade name does not constitute an endorsement or recommendation.
    yExact nutrient concentration of the fertilizer material may vary depending on commercial source.
    ________________________________________________________________________

    Table 3. Examples of formulations using pre-mixed commercial materials.
    Stage of growth
    1 2 3 4 5
    Transplant to 1st
    cluster set
    1st cluster to
    2nd cluster
    2nd cluster to
    3rd cluster
    3rd cluster to
    5th cluster
    5th cluster to
    termination
    ---------------------------Pre-mix 1 (4-18-38)------------------------
    1 2 3 4 5
    A Stock 16 lb. Pre-mix 1
    10 lb. MgSO
    4
    16 lb. Pre-mix 1
    10 lb. MgSO
    4
    16 lb. Pre-mix 1
    10 lb. MgSO
    4
    16 lb. Pre-mix 1
    12 lb. MgSO
    4
    16 lb. Pre-mix 1
    12 lb. MgSO
    4
    B Stock 7.5 lb. Ca(NO
    3
    )
    2
    9.5 lb. Ca(NO
    3
    )
    2
    12.0 lb. Ca(NO
    3
    )
    2
    16.5 lb. Ca(NO
    3
    )
    2
    20.5 lb. Ca(NO
    3
    )
    2
    -------------------------final concentrations (ppm)-------------------
    N 70 82 100 124 148
    P 49 49 49 49 49
    K 200 200 200 200 200
    Ca 56 71 94 124 154
    Mg 40 40 40 48 48
    S 50 50 50 60 60
    Fe 2.5 2.5 2.5 2.5 2.5
    Cu 0.3 0.3 0.3 0.3 0.3
    Mn 1.3 1.3 1.3 1.3 1.3
    Zn 0.3 0.3 0.3 0.3 0.3
    B 1.3 1.3 1.3 1.3 1.3
    Mo 0.06 0.06 0.06 0.06 0.06
    ----------------------------------Pre-mix 2 (3-15-27)---------------------------
    A Stock 20 lb Pre-mix 2 20 lb Pre-mix 2 20 lb Pre-mix 2 20 lb Pre-mix 2
    2 lb MgSO
    4
    20 lb Pre-mix 2
    2 lb MgSO
    4
    B Stock 7.5 lb Ca(NO
    3
    )
    2
    9.2 lb Ca(NO
    3
    )
    2
    12. 4 lb Ca(NO
    3
    )
    2
    15.7 lb Ca(NO
    3
    )
    2
    19 lb Ca(NO
    3
    )
    2 2 lb KNO
    3
    -------------------------final concentrations (ppm)---------------------------
    N 70 80 100 120 150
    P 51 51 51 51 51
    K 178 178 178 178 208
    Ca 57 69 93 118 143
    Mg 42 42 42 50 50
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 7
    Table 3. Examples of formulations using pre-mixed commercial materials.
    S (est.) 50 50 50 60 60
    Fe 3.6 3.6 3.6 3.6 3.6
    Cu 0.09 0.09 0.09 0.09 0.09
    Mn 0.45 0.45 0.45 0.45 0.45
    Zn 0.27 0.27 0.27 0.27 0.27
    B 1.35 1.35 1.35 1.35 1.35
    Mo 0.09 0.09 0.09 0.09 0.09
    --------------------------Pre-mix 3 (5-11-26)----------------------------
    1 2 3 4 5
    A Stock 27 lb Pre-mix 3
    10 lb. MgSO
    4
    27 lb Pre-mix 3
    10 lb. MgSO
    4
    27 lb Pre-mix 3
    10 lb. MgSO
    4
    27 lb Pre-mix 3
    12 lb. MgSO
    4
    27 lb Pre-mix 3
    12 lb. MgSO
    4
    B Stock 2.8 lb Ca(NO
    3
    )
    2
    4.4 lb Ca(NO
    3
    )
    2
    7.7 lb Ca(NO
    3
    )
    2
    11 lb Ca(NO
    3
    )
    2
    16 lb Ca(NO
    3
    )
    2
    ----------------------final concentrations (ppm)----------------------
    N 70 80 100 120 150
    P 51 51 51 51 51
    K 232 232 232 232 232
    Ca 21 33 58 83 120
    Mg 40 40 40 50 50
    S 50 50 50 60 60
    Fe 3.3 3.3 3.3 3.3 3.3
    Cu 0.17 0.17 0.17 0.17 0.17
    Mn 0.55 0.55 0.55 0.55 0.55
    Zn 0.17 0.17 0.17 0.17 0.17
    B 0.55 0.55 0.55 0.55 0.55
    Mo 0.11 0.11 0.11 0.11 0.11
    -----------------------Pre-mix 4 (7-17-37)-----------------------
    1 2 3 4 5
    A Stock 17 lb. Pre-mix 4
    10 lb. MgSO
    4
    17 lb. Pre-mix 4
    10 lb. MgSO
    4
    17 lb. Pre-mix 4
    10 lb. MgSO
    4
    17 lb. Pre-mix 4
    12 lb. MgSO
    4
    17 lb. Pre-mix 4
    12 lb. MgSO
    4
    B Stock 4 lb. Ca(NO
    3
    )
    2
    6 lb. Ca(NO
    3
    )
    2
    9 lb. Ca(NO
    3
    )
    2
    12 lb. Ca(NO
    3
    )
    2
    17 lb. Ca(NO
    3
    )
    2
    --------------------------final concentrations (ppm)----------------------
    N 71 83 101 119 149
    P 49 49 49 49 49
    K 208 208 208 208 208
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 8
    Table 3. Examples of formulations using pre-mixed commercial materials.
    Ca 30 45 67 89 127
    Mg 40 40 40 48 48
    S 50 50 50 60 60
    Fe 2.7 2.7 2.7 2.7 2.7
    Cu 0.07 0.07 0.07 0.07 0.07
    Mn 0.67 0.67 0.67 0.67 0.67
    Zn 0.14 0.14 0.14 0.14 0.14
    B 1.2 1.2 1.2 1.2 1.2
    Mo 0.07 0.07 0.07 0.07 0.07
    NOTE: Calculations in above table are for amount of fertilizer material in 30-gal stock tanks and then for a 1:100 dilution (1 gal each
    stock in 100 gals final nutrient solution). Fertilizer amounts placed in each stock tank will need to be doubled if fertilizer
    proportioner (1:100) pumps are installed in parallel in same incoming water line.
    Ca, Mg, and S values will vary upwards depending on the amount of Ca and Mg coming from the water source, and the of S coming
    from the sulfuric acid used for acidification.

    ______________________________________________________________________________

    Table 4. The following list provides the ppm of a specific nutrient provided by a specified amount of a particular fertilizer
    material for a 30-gal stock tank and a final dilution of 1:100.
    Amount of material Material ppm nutrient provided
    1 lb Potassium nitrate 5 ppm N
    14.5 ppm K
    1 lb Ammonium nitrate 13.3 ppm N
    1 lb Potassium chloride 20.3 ppm K
    1 lb Magnesium sulfate 4 ppm Mg
    5.6 ppm S
    1 pint Liquid calcium nitrate 4.2 ppm N
    6.6 ppm Ca
    1 lb Dry calcium nitrate 6.1 ppm N
    7.5 ppm Ca
    1 lb Calcium chloride 14.3 ppm Ca
    1 quart Phosphoric acid 30 ppm P
    1 gramz Solubor 0.018 ppm B
    0.5 lb Fe 330 chelated iron 2.0 ppm Fe
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 9
    Table 4. The following list provides the ppm of a specific nutrient provided by a specified amount of a particular fertilizer
    material for a 30-gal stock tank and a final dilution of 1:100.
    100 grams S.T.E.M. 0.12 ppm B
    0.28 ppm Cu
    0.66 ppm Fe
    0.70 ppm Mn
    0.0035 ppm Mo
    0.39 ppm Zn
    1 gram Copper sulfate 0.021 ppm Cu
    1 gram Manganese sulfate 0.024 ppm Mn
    1 gram Zinc sulfate 0.03 ppm Zn
    1 ml Liquid sodium molybdate 0.02 ppm Mo
    1 gram Dry sodium molybdate 0.03 ppm Mo
    1 lb Monopotassium Phosphate 9 ppm P
    11 ppm K
    zA gram scale or laboratory pipette will be needed to measure amounts of micronutrients or to calibrate a measuring spoon
    set to provide the correct amount of micronutrient materials. The following are some approximate equivalences for
    measuring dry fertilizer materials.
    Approximate weight (grams) for several measuring utensils
    Fertilizer 1 teaspoon (level) 1 tablespoon (level) one dry "ounce" in
    measuring cup
    Sequestrene Fe 330 4 14 20
    Ammonium molybdate 7 - -
    Sodium molybdate 4 - -
    Solubor 2 6 10
    S.T.E.M. 5 14 25
    Manganese sulfate 6 16 30
    Zinc sulfate 5 13 26
    Copper sulfate 7 20 35

    ___________________________________________________________________________________

    Table 5. Several examples of tomato nutrient solution formulations using the “formula method” with individual
    ingredients.
    Stage of growth
    1 2 3 4 5
    Transplant to 1st
    cluster
    1st cluster to
    2nd cluster
    2nd cluster to
    3rd cluster
    3rd cluster to
    5th cluster
    5th cluster to
    termination
    ----------------------------------FORMULA 1-------------------------------
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 10
    Table 5. Several examples of tomato nutrient solution formulations using the “formula method” with individual
    ingredients.
    A Stock 3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    3.3 pts
    Phos acid
    3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    6 lb. KCl
    10 lb. MgSO
    4
    6 lb. KCl
    10 lb. MgSO
    4
    6 lb. KCl
    10 lb. MgSO
    4
    2 lb. KNO
    3
    6 lb. KCl
    12 lb. MgSO
    4
    2 lb. KNO
    3
    6 lb. KCl
    12 lb. MgSO
    4
    6 lb. KNO
    3
    1 lb. NH
    4
    NO
    3
    10 gr CuSO
    4
    35 gr MnSO
    4
    10 gr ZnSO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr CuSO
    4
    35 gr MnSO
    4
    10 gr ZnSO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr CuSO
    4
    35 gr MnSO
    4
    10 gr ZnSO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr CuSO
    4
    35 gr MnSO
    4
    10 gr ZnSO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr CuSO
    4
    35 gr MnSO
    4
    10 gr ZnSO
    4
    40 gr Solubor
    3 ml Na Moly
    B Stock 2.1 gal.
    Ca(NO
    3
    )
    2
    2.4 gal.
    Ca(NO
    3
    )
    2
    2.7 gal.
    Ca(NO
    3
    )
    2
    3.3 gal.
    Ca(NO
    3
    )
    2
    3.3 gal.
    Ca(NO
    3
    )
    2
    or 11.5 lb dry
    Ca(NO
    3
    )
    2
    or 13.1 lb dry
    Ca(NO
    3
    )
    2
    or 14.8 lb dry
    Ca(NO
    3
    )
    2
    or 18.0 lb dry
    Ca(NO
    3
    )
    2
    or 18.0 lb dry
    Ca(NO
    3
    )
    2
    0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330
    ----------------------final concentrations (ppm)------------------------
    N 70 80 100 120 153
    P 50 50 50 50 50
    K 119 119 148 148 206
    Ca 111 (86)z 127 (98) 143 (111) 174 (135) 174 (135)
    Mg 40 40 40 48 48
    S 56 56 56 66 66
    Fe 2.8 2.8 2.8 2.8 2.8
    Cu 0.2 0.2 0.2 0.2 0.2
    Mn 0.8 0.8 0.8 0.8 0.8
    Zn 0.3 0.3 0.3 0.3 0.3
    B 0.7 0.7 0.7 0.7 0.7
    Mo 0.06 0.06 0.06 0.06 0.06
    ---------------------------------FORMULA 2-------------------------------
    A Stock 3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    3.3 pts
    Phos. acid
    6 lb KCl
    10 lb. MgSO
    4
    6 lb KCl
    10 lb. MgSO
    4
    6 lb KCl
    10 lb. MgSO
    4
    2 lb. KNO
    3
    6 lb KCl
    12 lb. MgSO
    4
    2 lb. KNO
    3
    6 lb KCl
    12 lb. MgSO
    4
    6 lb. KNO
    3 1 lb. NH
    4
    NO
    3
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 11
    Table 5. Several examples of tomato nutrient solution formulations using the “formula method” with individual
    ingredients.
    B Stock 2.1 gal
    Ca (NO
    3
    )
    2
    2.4 gal
    Ca (NO
    3
    )
    2
    2.7 gal
    Ca (NO
    3
    )
    2
    3.3 gal
    Ca (NO
    3
    )
    2
    3.3 gal
    Ca (NO
    3
    )
    2
    or 11.5 lb dry
    Ca (NO
    3
    )
    2
    or 13.1 lb dry
    Ca (NO
    3
    )
    2
    or 14.8 lb dry
    Ca (NO
    3
    )
    2
    or 18.0 lb dry
    Ca (NO
    3
    )
    2
    or 18.0 lb dry
    Ca (NO
    3
    )
    2
    0.5 lb Fe 330 0.5 lb Fe 330 0.5 lb Fe 330 0.5 lb Fe 330 0.5 lb Fe 330
    ---------------------------final concentrations (ppm)--------------------------
    N 70 80 100 120 150
    P 50 50 50 50 50
    K 119 119 148 148 206
    Ca 111(86)z 127(98) 143(111) 174(135) 174(135)
    Mg 40 40 40 48 48
    S 56 56 56 66 66
    Fe 2.7 2.7 2.7 2.7 2.7
    Cu 0.28 0.28 0.28 0.28 0.28
    Mn 0.7 0.7 0.7 0.7 0.7
    Zn 0.39 0.39 0.39 0.39 0.39
    B 0.84 0.84 0.84 0.84 0.84
    Mo 0.06 0.06 0.06 0.06 0.06
    ---------------------------------FORMULA 3---------------------------------
    A Stock 5.5 lb KH
    2
    PO
    4
    4 lb KNO
    3 10 lb MgSO
    4
    5.5 lb KH
    2
    PO
    4
    4 lb KNO
    3 10 lb MgSO
    4
    5.5 lb KH
    2
    PO
    4
    5 lb KNO
    3 10 lb MgSO
    4
    1 lb KCl
    5.5 lb KH
    2
    PO
    4
    8 lb KNO
    3 12 lb MgSO
    4
    1 lb KCl
    5.5 lb KH
    2
    PO
    4
    8 lb KNO
    3 12 lb MgSO
    4
    1 lb KCl
    2 lb NH
    4
    NO
    3
    10 gr Cu SO
    4
    35 gr Mn SO
    4
    10 gr Zn SO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr Cu SO
    4
    35 gr Mn SO
    4
    10 gr Zn SO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr Cu SO
    4
    35 gr Mn SO
    4
    10 gr Zn SO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr Cu SO
    4
    35 gr Mn SO
    4
    10 gr Zn SO
    4
    40 gr Solubor
    3 ml Na Moly
    10 gr Cu SO
    4
    35 gr Mn SO
    4
    10 gr Zn SO
    4
    40 gr Solubor
    3 ml Na Moly
    B Stock 1.5 gal
    Ca(NO
    3
    )
    2
    1.8 gal
    Ca(NO
    3
    )
    2
    2.2 gal
    Ca(NO
    3
    )
    2
    2.4 gal
    Ca(NO
    3
    )
    2
    2.5 gal
    Ca(NO
    3
    )
    2
    or 8.2 lb dry
    Ca(NO
    3
    )
    2
    or 9.8 lb dry
    Ca(NO
    3
    )
    2
    or 12.3 lb dry
    Ca(NO
    3
    )
    2
    or 13.1 lb dry
    Ca(NO
    3
    )
    2
    or 13.7 lb dry
    Ca(NO
    3
    )
    2
    0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330 0.7 lb Fe 330
    ------------------------final concentrations (ppm)----------------------
    N 70 80 100 120 150
    P 50 50 50 50 50
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 12
    Table 5. Several examples of tomato nutrient solution formulations using the “formula method” with individual
    ingredients.
    K 119 119 153 153 196
    Ca 79(61)z 94(74) 118(92) 126(98) 131(103)
    Mg 40 40 40 48 48
    S 56 56 56 66 66
    Fe 2.8 2.8 2.8 2.8 2.8
    Cu 0.2 0.2 0.2 0.2 0.2
    Mn 0.8 0.8 0.8 0.8 0.8
    Zn 0.3 0.3 0.3 0.3 0.3
    B 0.7 0.7 0.7 0.7 0.7
    Mo 0.06 0.06 0.06 0.06 0.06
    ----------------------------FORMULA 4----------------------------
    A Stock 3.3 pts
    Phos. acid
    8.3 lb. KNO
    3
    10 lb. MgSO
    4
    3.3 pts
    Phos. acid
    8.3 lb. KNO
    3
    10 lb. MgSO
    4
    3.3 pts
    Phos. acid
    10.3 lb. KNO
    3
    10 lb. MgSO
    4
    3.3 pts
    Phos. acid
    10.3 lb. KNO
    3
    12 lb. MgSO
    4
    3.3 pts
    Phos. acid
    13.8 lb. KNO
    3
    12 lb. MgSO
    4
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    100 gr. S.T.E.M.
    40 gr. Solubor
    3 ml Na Moly
    B Stock 6.7 pt.
    Ca(NO
    3
    )
    2
    9 pt.
    Ca(NO
    3
    )
    2
    11.4 pt.
    Ca(NO
    3
    )
    2
    2 gal.
    Ca(NO
    3
    )
    2
    2.4 gal.
    Ca(NO
    3
    )
    2
    or 4.6 lb. dry
    Ca(NO
    3
    )
    2
    or 6.2 lb. dry
    Ca(NO
    3
    )
    2
    or 7.9 lb. dry
    Ca(NO
    3
    )
    2
    or 11.1 lb. dry
    Ca(NO
    3
    )
    2
    or 13.3 lb. dry
    Ca(NO
    3
    )
    2
    0.7 lb. Fe 330 0.7 lb. Fe 330 0.7 lb. Fe 330 0.7 lb. Fe 330 0.7 lb. Fe 330
    ---------------------final concentrations (ppm)------------------------
    N 70 80 100 120 150
    P 50 50 50 50 50
    K 120 120 150 150 200
    Ca 44(35)z 59(47) 75 (59) 105 (83) 127 (100)
    Mg 40 40 40 48 48
    S 56 56 56 67 67
    Fe 2.7 2.7 2.7 2.7 2.7
    Cu 0.28 0.28 0.28 0.28 0.28
    Mn 0.7 0.7 0.7 0.7 0.7
    Zn 0.39 0.39 0.39 0.39 0.39
    B 0.84 0.84 0.84 0.84 0.84
    Nutrient Solution Formulation for Hydroponic (Perlite, Rockwool, NFT) Tomatoes in Florida 13
    Table 5. Several examples of tomato nutrient solution formulations using the “formula method” with individual
    ingredients.
    Mo 0.06 0.06 0.06 0.06 0.06
    ZNumbers in parentheses are the ppm Ca when dry Ca(NO
    3
    )
    2
    is used instead of liquid.
    NOTE: Calculations in above table are for amount of fertilizer material in 30-gal stock tanks and then for a 1:100 (1 gal
    each stock in 100 gals final nutrient solution). Fertilizer amounts placed in each stock tank will need be doubled if
    proportioner (1:100) pumps are installed in parallel in same incoming water line.
    Ca, Mg, and S values will vary upwards depending on the amount of Ca and Mg coming from the water source, and the
    amount of S coming from the sulfuric acid used for acidification.
     
  4. So, If you made it this far and your eyes are still in there sockets you deserve a reward!!:hello:

    I doubt if the above info will help the hobby grower but again i know of more than a few that can read and understand this. For you that can i hope it helps in some way.

    Peace...:wave:
     

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