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    • 专利摘要:
    Composition of a liquid fertilizer containing as main base the primary nutrients such as nitrogen, phosphorus and potassium, calcium as a secondary element and traces of trace elements, with this composition a single liquid fertilizer is obtained to make nutritious applications both to the soil and to the foliage of the plant boosted in this way the synergy between the rhizosphere and the phylosphere, it is possible to automatically maintain a ph between 5.5 and 6.5 of the liquid medium, thus promoting maximum availability and maximum assimilation of all the nutrients, and finally it can be applied with electro conductivities of up to 12 ds/m without risk of damaging the plants as it increases the capacity to withstand greater internal osmotic pressures favoring cell division and reinforcing cell walls. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2651696A1
    申请号:ES201600623
    申请日:2016-07-29
    公开日:2018-01-29
    发明作者:Naser HAMID TLAIE;Fares TLAIE SINAID
    申请人:Factor Humus Espana S L;Factor Humus Espana Sl;
    IPC主号:
    专利说明:

     DESCRIPTION Liquid fertilizer, composition and properties. 1. TECHNICAL SECTOR The present invention falls within the technical sector of the 5-fertilizer qUlmlca: These are substances that contain nutritional elements whose composition is developed in such a way that they can be absorbed by plants. They are used to increase production, replenish and avoid nutrient deficiencies and tend to improve their health. 2. STATE OF THE TECHNIQUE 10 Definition of Fertilizers according to FAO: substances that provide nutrients that the plant needs. The nutritional elements of which the fertilizers are composed are classified into macro elements, secondary elements and micro element or trace elements, according to the quantity needs that the plants require for their development. The following table shows the main elements according to their classification: Table 1. Essential elements for the nutrition of plants classified according to importance. Micro elements) Mannoso Phosphorus Magnesium (Mg) Copper Potassium Sulfur s Zinc Molybdenum Iron Boron NITROGEN, PHOSPHORUS AND POTASSIUM The functions of nitrogen, phosphorus and potassium, as well as their behavior in soil and plant are different. After water, nitrogen is the most important nutrient in the development of the plant given its abundance in the main biomolecules of living matter. The preferred ionic forms of nitrogen uptake by the root are nitrate (N03 ') and ammonium (NH / L. Also by the absorption of ammonia (gas) that is introduced into the plant through stomata, becoming ammonium In the plant, N is distributed in three groups: more than 50% is found in compounds of high molecular weight (proteins and nucleic acids): the rest, in the form of soluble organic N (amino acids, amides, amines ... ) and inorganic N (mainly nitrate and ammonium ions).Its content in the total dry weight of the plant ranges between 1.5 and 5%. Nitrogen is responsible for feeding microorganisms and thus favoring the breakdown of organic matter. This element dissolves easily in soil water and is partially retained by its particles, 5 thus, it is easily lost by leaching. Nitrogen gives plants a green color, allows rapid growth. If care is not taken at the time of application and is supplied in excessive quantities, there is a risk of delaying the maturation of plants and leaving them susceptible to diseases. Phosphorus is available to the plant as phosphate ion. In contrast to nitrogen, phosphorus is not found in reduced form in plants, but remains as a phosphate either in free form or as an organic compound, mainly as a phosphoric ester with hydroxyl groups, or forming energy-rich anhydrous bonds , as is the case with the ATP or the ADP. It plays, therefore, a key role in photosynthesis, respiration and in all energy metabolism. 15 Likewise, phosphorus plays an important structural role in many cellular molecules and structures, as in the case of the diester bonds present in nucleic acids and in phospholipids, which are fundamental in membrane structures. However, an important part of the phosphate in the plant is in free ionic form: 75% in vacuoles and the remaining 25%, in matrix 20 and cytoplasmic organelles in equilibrium with metabolic cycles. Phosphate is easily redistributed in most plants from one organ to another, accumulating in young leaves and developing flowers and seeds. Phosphorus is responsible for stimulating the formation and early growth of roots, bringing a start Vigorous and fast plant. Phosphorus 25 is also responsible for stimulating flowering, accelerating maturity and helping seed formation, also improves resistance against the effect of low temperatures. Phosphorus is an element that reacts quickly with other chemical elements in the soil, which is why less soluble components are formed causing few proportions of this element to be available for the plant. This process is known as fixation. Phosphate is not lost by leaching. Potassium, together with P and N, is the main content of the most commercialized fertilizers due to the importance of these three elements. His behavior, despite his cationic nature. It is very similar to that presented by phosphorus and nitrogen, redistributing very easily from mature to juvenile organs due to their solubility and low affinity for organic ligands, which are easily exchanged. It is the most abundant cation in the vacuole and cytoplasm, where it can reach concentrations of 100 mM and between 2000-5000 ppm in the xylem. It plays, therefore, a key role in the osmoregulation that takes place in the stomatic opening and closing processes, as well as in the nastias and tactisms.On the other hand, K is the activator of more than 50 enzyme systems, among which oxidoreductases, dehydrogenases, transferases, synthetases and kinases stand out. Although it may be substituted in some cases, as it is only necessary for the conformational change of the apoenzyme, given the high concentrations necessary, sometimes it is difficult to consider a substitute in vivo. Potassium, on the other hand, is easily retained by soil particles and its depletion is mainly due to the intensive exploitation of plants that require high amounts of this element. Potassium is responsible for increasing the level of disease resistance in plants as well as giving them greater vigor. 10 It also improves the resistance of plants against the effects of cold temperatures. With the help of these elements, grains and seeds improve their filling, roots and tubers maintain their development and prevent bedding. Potassium is essential for the formation and transfer of starches, sugars and oils in addition to regulating water consumption in plants. 15 CALCIUM Calcium is absorbed as divalent Ca2 + ion. It is much more mobile in the apoplasto than in the simplasto, reason why those organs that receive the water mainly by this route can present problems in the supply of the cation. Deficiency symptoms are always more evident in young tissues and meristematic areas of roots, stems and leaves. There are two main reasons that explain this fact: on the one hand, cell division is affected by calcium deficiency and in the mentioned tissues the mitotic index is high; on the other, the middle lamina formed between two daughter cells, one of whose main components is calcium pectate, can be altered. 25 Calcium is also required for the integrity and functionality of membranes and, recently, it has been implicated as a second messenger in the functioning of some hormones and in environmental responses. As a second messenger, it is involved in the phosphorylation of some proteins, so that Ca can play an important role in the activity and regulation of some enzymes. Its reversible binding to a small cytosolic protein (calmodulin), allows it to play an important role as an enzyme modulator and play a fundamental role in the world of cell signals and plant development, as has been demonstrated in the animal cell. Calcium is responsible for helping the decomposition of organic matter 35 and the release of nutrients while improving the structure of the soil and water retention. However, the excess of this element in the soil causes a deficiency of potassium, phosphorus, magnesium zinc and iron.5 MICRO NUTRIENTES These are the nutritional elements that are required in small and very limited proportions, but, if one or more of these are lacking, the impact on the development and yield of the crops is great. FERTILIZING APPLICATIONS There are different ways of applying fertilizers, but in a very summarized way and within the most usual, they can be classified as follows: To the ground 10 To the foliage (foliar) and With the irrigation water: fertigation For plants have a healthy development both in growth and in health require various nutritional elements obtained mainly from the soil and for this it is necessary that the soil contains a wide range of nutrients, but these elements are not always present in the soil, therefore the Plants suffer from obstruction to growth and are more sensitive to diseases and pests. When the soil is deficient in any of these essential elements for its development, it is a common practice to incorporate a fertilizer into it, in order to inhibit physiological lesions and strengthen the plant. 20 It has traditionally been considered that the form of nutrition for plants is through the soil, where it is assumed that the roots of the plant will absorb the water and the necessary nutrients. However, in recent years, foliar fertilization has been developed to provide plants with their real nutritional needs. Foliar fertilization is a reliable method for fertilizing plants 25 when nutrition from the soil is inefficient. Foliar fertilization is a "by-pass" approach that complements conventional applications of edaphic fertilizers, when they do not develop well enough. Foliar application overcomes the limitations of soil fertilization such as leaching, precipitation of insoluble fertilizers, antagonism between certain nutrients, heterogeneous soils that are unsuitable for low dosages, and fixation / absorption reactions as in the case of phosphorus and potassium. At present there are only fertilizers conditioned to the mode of application mainly due to their origin in formulation (the characteristics they have have different properties and different effects at the time of application) and their assembly, which are distinguished by their applications when soil (either directly or through fertigation) or to the foliage.Therefore, the state of the art determines that there are only fertilizers formulated for soil applications or fertilizers formulated for foliar applications. 5 The pH is a fundamental constant that influences the vital physiological processes of nutrient absorption at the root level and at the leaf level. The enzymatic action and the chemical transformations of the cells are carried out within strict pH ranges. The root and foliar systems of each species are adapted to characteristic pH, so any change in the 10 ideal conditions leads to greater difficulties in their development. In other words, outside of this range, root and foliar absorption is difficult or, where appropriate, impossible. The pH affects in an important way the availability or non-availability of nutrients for the plant. 15 The pH of the solutions provided to the soil or to the leaves, in their contact area, affects plant nutrition in several ways, among which it should be noted: The pH can affect the availability of nutrients in different grades and forms. In a very generic way it can be said that the root and foliar system of the plants absorb the nutrients that are dissolved in the water. Extreme pH values, whether due to acidity or alkalinity, can cause the precipitation of certain chemical elements, thus remaining in a form not available for crops. When it comes to essential nutrients, it is obvious to point out that the plant species will suffer problems to feed, so it will negatively affect its development and production can even ruin the crops, if corrective measures are not taken. To demonstrate the importance of pH by way of example, it can be mentioned that in humans the extreme values compatible with life and with the maintenance of vital functions range between 6.8 and 7.8; the narrow margin of 7.35 to 7.45 30 being normal. Also in laboratory work, it is essential to maintain a pH for the performance of many chemical-biological reactions. An adequate control of the fertilization demands the adjustment of the pH in the nutrient solution to a predetermined optimum values. The pH of the nutrient solution is a parameter whose control and adjustment depends on the efficiency of fertilization. Its importance is explained both by the requirement of maintaining an optimal pH in terms of favoring the availability and assimilability of the nutritive elements for plants, and the need to generate pH conditions tending to prevent the formation of precipitates and consequent obstructions in The different components of the installation.As a consequence, and in accordance with the numerous studies that have been carried out in this regard, it is generally understood that the nutrient solution must be adjusted to a pH between the values of 5.5 and 6.5. The range of nutrient availability for plants according to the incidence 5 of the pH in the nutrient broth is as follows: Illustration 1. Interval of absorption of nutrients by the plant according to the pH of the medium. Below is a descriptive table of the existing pH ranges in which the nutrient solutions can be established and the implications that entails, with respect to nutrient assimilation, being in a pH range or another: Table 2. Description of the Interval of absorption of nutrients by the plant according to the pH of the medium. PH range Classification Below 4.5 Extremely acidic From 4.5 to 5 Very strongly acidic From 5.1 to 5.4 Strongly acidic From 5.5 to 6 Mediumly acidic From 6.1 to 6.6 Highly acidic From 6, 7 to 7.3 Neutral Remarks Conditions of availability of very unfavorable nutrients Conditions of availability of unfavorable nutrients. There is a possible toxicity due to the effect of aluminum Causes problems of availability of ca, K, M N P, SyMo Nutrient solution suitable for most crops This is where the maximum nutrient availability is foundFrom 7.4 to 7.8 Medium basic There is generally no good availability of nutrients From 7.9 to 8.4 Basic Decreases the availability of P and Bo, in addition there is a growing non-availability of Cu, Fe, Mn, Zn and Co. From 8.5 to 9 Slightly alkaline Major problems of unavailability appear Onibilldad From 9.1 to 10 Alkaline There is low nutrient availability Above 10 Strongly alkaline It carries a high percentage of nutrient unavailability Addressing the fact that the vast majority of irrigation waters, with or without the addition of agricultural inputs, have a pH higher than 6.6, the most common case is the one that implies the need to reduce their pH to the values indicated above or / and the adjustment for pH waters with values below 5.4 (normally achieved by the addition of agricultural inputs), in both cases they imply the addition of an acid (usually nitric acid, potassium nitrate, phosphoric acid, acetic acid, etc.) or the addition of an alkaline agent, respectively. Below is a table of the usual fertilizers with an acidic or basic character to adjust the nutrient solutions to a suitable pH range: Table 3. Fertilizers used as acids or as bases to lower or raise the pH of the medium respectively. Acidifying power (meq / g of H +) and alkalizing power (meq / g of OH-) of 15 acidic and basic fertilizers, respectively, used in fertirrigation. (Fuentes Méndez, SA 1999.) Fertilizer Acidifying power Nitric Acid 54% 8.60 meq Ig of H + Phosphoric Acid 75% (white) 7.65 meq Ig of H + Phosphoric Acid 72% (green) 7.30 meq lB of H + Potassium solution (1.8) - 0-105 1.43 meq Ig of H + PK solution 0-20-10 1.21 meq lB of H + Potassium solution (1.3) -0-lOP 1.20 meq Ig of H + Potassium solution (2) -O-10NS Potassium solution (1.4) -0 -10NP 0.05 meq Ig of H + MagneSium Nitrate Solution 0.00 meq 18 of H + Magnesium Sulfate Solution 0.00 meq Ig of H + Nitrogenous solution N20 0.03 meq of OH "Solution PK 0-15-15 1.10 meq Ig of OH" Solution Potassium 0-0-23 4.90 meq lB of OH "5 10 The pH values reached by the usual fertilizers applied in agriculture in a saturated solution of irrigation water are shown below (Hauck 1984): Table 4. pH of the usual fertilizers in irrigation water. Product pH of the saturated solution Urea> 9.0 Ammonium nitrate 4.7 Calcium nitrate 7.0 Potassium nitrate 7.0 Ammonium sulfate 5.4 Ammonia water> 9.0 Monoammonium phosphate 3.5 Diammonium phosphate 8.0 Triple superphosphate 1.0 Therefore the state of the technique determines that the optimum pH ranges for the nutritive solutions are between 5.5 and 6.5, and that the fertilizers currently available only have an acidifying or alkalizing character to respectively raise or lower the pH of the nutrient solutions. ELECTRO CONDUCTIVITY (EC) For proper management of liquid fertilizers in addition to the pH data described above requires knowledge of their salinity index at different doses of application of the product in a nutrient solution. The salinity index of a fertilizer is an indicative figure of the degree in which a given quantity of the product increases the osmotic pressure of the nutrient solution. Osmotic pressure is a physicochemical property of nutritional solutions, which depends on the amount of dissolved particles or solutes. Water and mineral salts, along with other solutes, play a vital role in the osmotic regulation of living things. Osmosis is a spontaneous phenomenon where water molecules tend to move from a less concentrated solution called hypotonic to a more concentrated or hypertonic solution separated by a semi-permeable membrane. These membranes, like those that exist in the cells, allow the passage of solvents but not of the solute. Therefore, when the water molecules diffuse from the hypotonic to the hypertonic solution, they generate an osmotic pressure (which is the force exerted to oppose the movement of water). The total amount of ions of the dissolved salts of fertilizers in the nutrient solution exert a force, the osmotic pressure; as the amount of ions increases the osmotic pressure increases.5 An indirect and empirical measure to determine the osmotic pressure of the nutrient solution is the electrical conductivity (EC), which serves to indicate the total concentration of dissolved salts in the water, but does not indicate which salts are present. The EC is expressed in dS / m (previously called mmho / cm). Excessive increases in electrical conductivity determine increases in osmotic pressure and this leads to difficulties in the absorption of nutrients and water by plants. Salinity is, perhaps, the most important problem that affects irrigated agriculture in arid and semi-arid areas. It is considered that at the moment a third 10 of the irrigated areas of the world, that suppose about three hundred million hectares, are affected by the salinity. Crops may have certain levels of salinity tolerance, however it should be taken into account that fertilization contributes to the increase in electrical conductivity, and therefore to the level of salinity. 15 Salinity negatively affects every aspect of the plant's physiology and its metabolism. The high concentration of salts causes an ionic imbalance and osmotic stress. Strong saline stress breaks homeostasis of water potential and ion distribution. It decreases the water potential of the environment and thus restricts water absorption 20 mainly by the roots (osmotic effect). Saline stress breaks the ionic homeostasis of plants by causing a toxic excess of sodium (Na +) in the cytoplasm and a deficiency of ions such as potassium (K +). This absorption determines its accumulation in tissues with concentrations that become toxic and induce physiological disorders (specific ionic toxicity). Saline stress inhibits plant growth, high concentrations of saline ions modify the absorption of essential nutrients by determining nutritional imbalances (nutritional effect). One cause of the growth reduction is inadequate photosynthesis due to stomatal closure and consequently the limitation of CO2 input. More important is, however, that stress inhibits cell division and expansion directly. One of the most sensitive physiological processes to water deficit is cell growth, cell expansion and leaf area are reduced. This decrease is due in part to the increase in energy expenditure made by the plant, to acquire the water and make the biochemical contribution to survive, energy is diverted that should be used for the processes associated with growth and yield, including cell elongation , synthesis of metabolites and cellular components. On the other hand, a low osmotic pressure, containing a deficit in the amount of nutrients in the nutrient solution, can induce nutritional deficiencies.In relation to electro conductivity, the Riverside Salinity Laboratory (USA) classifies water into the following six groups: Table 5. Classification of water for irrigation according to the index of salts dissolved in them. Classification of waters according to their salinity index measured by Electro Conductivities (EC) (dS / m) EC GROUP (dS / m) Salinity Observations 1 From 0.10 to 0.25 2 From 0.25 to 0.75 3 From 0.75 to 2.25 4 From 2.25 to 4.00 5 From 4.00 to 6.00 6 From 6.00 to 10.00 Low Salinity Salinity Medium Salinity High Salinity Very High Excessive Salinity Suitable for irrigation of any crop. Most crops resist this water without special control practices. Use only for salt resistant crops. In many cases not recommended for irrigation. Only for crops very tolerant to salinity. It should only be used in very special cases, taking extreme precautions. Water not advisable for irrigation under any circumstances 5 Therefore, the state of the art determines that the nutritive solutions must have intervals of electro conductivities between 0.10 to 2.25 dS / m maximum, in order not to cause irreversible physiological and metabolic damage to the plants.3. OBJECT OF THE INVENTION The present invention defends the following technological development of a fertilizer liquid: 5 Firstly: At present there are only fertilizers conditioned to the mode of application: -to soil (either directly or through fertigation) or - to the foliage The formulations of each of the fertilizers are different if their destination application is going to be to the soil or to the foliage. The present invention proposes a liquid fertilizer product that is not conditioning for both root and foliar application, that is, the liquid fertilizer of the present invention can be applied to all types of plants both to the soil and to the foliage, thus promoting the synergy between the rhizosphere and the philosophy ensuring that all 15 physiological processes in the plant are balanced. It can also be used as a pre-germination solution applied to the seeds. Second: The vast majority of irrigation waters or nutritive solutions have a pH higher than 6.6, the most common case is the one that implies the need to lower the pH of these o / and the adjustment for water or nutrient solutions 20 of pH with values below 504. In both cases it involves the addition of an acid (usually nitric acid, potassium nitrate, phosphoric acid, acetic acid, etc.) or the addition of an alkaline agent to regulate the pH of irrigation water or nutrient solutions and thus obtain an optimal pH and maximize the availability of nutrients. The present invention proposes a liquid fertilizer product intended to be added and / or combined with the irrigation water and / or nutrient solution, to perform its function of fertilizer itself and with which it is possible to buffer the pH of the liquid medium ( before an irrigation water and / or acidic or basic nutrient solution is able to react opposing the part of acidic or basic component to maintain the pH in a range between 5.5 and 6.5), interval in which the maximum availability of nutrients is found to be assimilated by plants. This translates into a maximum level of nutrient assimilation by the plant and also significantly reduces the loss of these, which places it at a very high level of sustainable natural resources management. Finally and thirdly: Excessive increases in electrical conductivity 35 determine increases in osmotic pressure and this leads to difficulties in the absorption of nutrients and water by plants, salinity negatively affects every aspect of the physiology of the plant and Your metabolism Strong saline stress breaks homeostasis of water potential and ion distribution, stress inhibits cell division and expansion, diverts energy that should be used for the 40 processes associated with growth and performance, including cell elongation, metabolite synthesis and Cellular components, therefore the present invention proposes a fertilizer liquid that can be applied with electro conductivity levels of up to 12dS / m without risk of damaging the plants. When the plantabsorbs these nutrients by osmosis, the elements that make up the present invention automatically increase the ability in the cell wall to withstand high osmotic pressures inside the cell. The protoplasm (nucleus and cytoplasm) also absorbs certain components of the product that reduce the amount of compounds that characteristically increase internal pressure. Cell division then occurs and the cell wall is reinforced. It regulates the entry of all available nutrients around without changing its role thus leading to cell division before the stretching or elongation is carried out as is the case with traditional fertilizers. The detailed description of the invention is developed below: The product object of the invention is obtained through several thermochemical reactions in which we differentiate exothermic reactions and endothermic reactions, in different ranges of concentrations by weight of the products named a continuation: Ammonium nitrate between 10-35%, Calcium Nitrate between 15 10-35%, Potassium Nitrate between 5-35%, Monoammonium Phosphate between 5-20%, Monopotassium Phosphate between 5-20 %, Potassium Chloride between 5-20%, Magnesium Sulfate between 1-10%, Iron Chelate between 0.05-10%, Boric Acid between 0.05-10%, Sulfate of Copper between 0.05-10%, Manganese Sulfate between 0.05-10%, Zinc Sulfate between 0.05-10%, Molybdenum between 0.01-10% 20 And finally a catalyst complex between 0.001-10%, which favors the thermochemical reactions of the process giving rise to the final product, the rest is water to complete 100% in each case. The composition resulting from the formation of the product of the invention, in percentages by weight, for the aforementioned purposes are: Total nitrogen of 5 to 15%, 25 Nitric nitrogen of 5 to 15%, Ammoniacal Nitrogen of 5 to 15%, Pentoxide of Phosphorus from 5 to 15%, Potassium Oxide from 5 to 15%, Calcium soluble from 0.5 to 8%, contains traces of secondary nutrients and trace elements such as Boron, Copper, Magnesium and Zinc, the rest until 100% of the composition is completed In each case it is water. In this way a liquid fertilizer based on the main macronutrients 30 such as Nitrogen, Phosphorus and Potassium is obtained, with which a unique liquid fertilizer is obtained to make applications both to the soil and to the foliage enhanced in this way the synergy of the plant soil-air, it is achieved that both irrigation water and nutritive solutions automatically maintain a pH between 5.5 and 6.5 thus promoting the availability and assimilation of all nutrients and finally it can be applied with electro conductivities of up to 12 dS / m if risk of damaging the plants and reinforcing their cell walls.The present invention is further illustrated by the following example of the composition of the final product, which is not intended to be limiting of its different combinations in percentages as appropriate: Example 1: 5 -Total Nitrogen 12% -Nitric Nitrogen 7% -Amoniacal Nitrogen 5% -Posphorus Pentoxide 8% -Potassium Oxide 7% 10 -Soluble Calcium 2% -B Boron, Copper, Iron, Magnesium, Zinc-The rest to complete 100% of the product is water 
    权利要求:
    Claims (4)
    [1]
    CLAIMS 1. A liquid fertilizer composition consisting of: a. Total nitrogen from 5 to 15%, 5 b. Nitric nitrogen from 5 to 15%, c. Ammonia Nitrogen from 5 to 15%, d. Phosphorus pentoxide from 5 to 15%, e. Potassium oxide from 5 to 15%, f. Soluble calcium from 0.5 to 8%, 10 g. It contains traces of secondary nutrients and trace elements such as Boron, Copper, Magnesium and Zinc. h. The rest until completing 100% of the composition in each case is water.
    [2]
    2. The composition according to claim 1, liquid fertilizer product, characterized in that its application can be to the soil V / or to the foliage of the plant. twenty
    [3]
    3. The composition according to claim 1, liquid fertilizer product, characterized in that it manages to automatically maintain the pH of the liquid medium between 5.5 and 6.5.
    [4]
    4. The composition according to claim 1, liquid fertilizer product, characterized in that it can be applied with electro conductivities of up to 12 dS / m without risk of damaging plants.
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    WO2012081970A2|2010-12-13|2012-06-21|Jq Biotech Sdn Bhd|A plant growth promoting composition|
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