FI105439B - Process, installation and agent for improving plant growth - Google Patents

Description

1 105439

Method, apparatus and substance for improving plant growth

The invention relates to a method for improving the growth of plants, wherein the method comprises administering an organic carbon compound by evaporation of the carbon compound to an appropriate concentration in an enclosed space such as the above-ground parts of plants in a greenhouse. The invention also relates to apparatus and material for improving plant growth.

The beneficial effect of methyl alcohol or methanol on plant growth has long been known, and this technique has been described e.g. in the article "The Path of Carbon in Photosynthesis: Improved Crop Yields with Methanol", A.M. Nonomura and A.A. Benson, Proc. Natl. Acad. Sci. USA, Vol. 89, pp. 9794-9798 (1992) and U.S. Patent No. 5,579,700. It has been found that plants are able to use methanol for metabolism to convert it into sugars. In practical experiments, various syringes or sprinklers have been used which spray the aqueous methanol solution at a suitable concentration on the leaves of the plants as a fine spray or mist. The concentration of methanol in the aqueous solution in these experiments has generally been 10-30%. An aqueous methanol solution was found to have a beneficial effect on plant welfare, especially at high temperatures and in direct sunlight. Some species have achieved up to 50% higher growth than non-methanol treated ones.

In addition, other lower apathetic alcohols (ethanol, propanol, butanol) have been found to have a growth promoting effect, as noted, inter alia, U.S. Patent 4,274,861.

In addition, a foliar fertilizer containing de-30 naturalized ethanol is known as a commercial product, which can enhance contact and improve plant fluid stress.

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Until now, alcohol solutions have been administered by conventional spraying, spraying and spraying methods in the open and in greenhouses. In this case, the problem is that the application of alcohol to the plants cannot be precisely controlled and controlled, or must be done precisely, for example, with a hand shower. Foliar spray may cause leaf damage due to technical condition of the delivery equipment and impurities. Plant status 2 105439 may occasionally allow strong concentrations, but in sensitive growth stages, such as after a cloudy period, may not be able to withstand the same concentrations. Spraying directly on the plants can also cause economically damaging appearance, eg. a rose or 5 other flowers with a small defect in the petal can make the product unsuitable for sale. The process further requires the preparation of an aqueous solution of alcohol of suitable strength and treatment and spraying of large volumes of alcoholic solution. In addition, due to the method of application, some of the solution is inevitably absorbed into the ground where it is wasted.

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From Finnish patent 96164 there is known a method in which methanol is administered to plants in a confined space, such as a greenhouse, by evaporation of the methanol to a closed concentration at a suitable concentration. This method is simple and does not require the handling and pumping of large volumes of aqueous solution. At its simplest, the method can employ an open, heated or unheated vessel, from which methanol can evaporate into the air surrounding the above-ground parts of the plants, causing a suitable concentration in the air. Because methanol is gaseous in the air, confined within the air, the plants are exposed to it evenly and there is no risk of uneven dosing, nor is the methanol used escaping, as is the case, for example, with outdoor plants. The patent also mentions the possibility of feeding methanol in the form of small droplets into an air stream which can be achieved by a propeller blower. The droplets evaporate into the air very quickly in this way. The patent also mentions the possibility of passing methanol as a thin layer through a suitable surface.

Dosing by evaporation is thus a practical solution. To date, however, no solution has been proposed for the efficient delivery of volatile carbon compounds in gaseous form to plants.

It is an object of the invention to provide a method and apparatus which can be used in existing greenhouses for the supply of alcohols or other volatile organic carbon compounds which promote the growth of green plants. To accomplish this purpose, the process is essentially characterized in that the compound is fed from a container containing the compound with a gas stream introduced from its own, enclosed air source from a separate gas source. Preferably, the gas source is a

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105439 source of other growth promoting material, in particular carbon dioxide.

The apparatus, in turn, is characterized in that the source of the volatile organic carbon compound is combined with a gas stream originating from a separate gas source from the enclosed air.

By combining the feed of the organic carbon compound with, for example, a gaseous carbon dioxide feed stream, the plants can be administered the same substances simultaneously and in a suitable proportion, e.g. to the amount of carbon dioxide administered. However, it is also possible to combine the feed of the organic carbon compound with another flow from a specific gas source. It is also within the scope of the invention to provide the Volatile Organic Compound feed from its own tank as such, where the tank serves as a source of gas flow for the gas.

It is also an object of the invention to provide a new agent for promoting plant growth in greenhouses. The substance of the invention comprises a mixture of a volatile organic carbon compound and carbon dioxide.

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The invention will now be described in more detail with reference to the accompanying drawings, in which Figure 1 illustrates one principle of the method, Figure 2 schematically illustrates the method applied to an existing system, and Figures 3-5 show the effect of a volatile organic carbon compound on plants.

. The method is used in a confined space 1, such as a greenhouse, which has normal ventilation with the outside air. At a convenient point within the enclosed space, which may be multiple sites, is a reservoir 2 containing 35 volatile organic carbon compounds from which a mixture of carbon dioxide and a volatile organic carbon compound such as ethanol or methanol is dispersed in space 1 in gaseous form.

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The reservoir 2, which acts as the source of the volatile organic carbon compound, is contacted with a flow of gaseous medium from a separate gas source from the indoor air of the enclosed space 1. Container 2 is a container that is open so that the compound can be evaporated into the air in the enclosed space 1 via the liquid content of the container with the flow of gaseous medium bubbling through. The vessel may be connected to a heater 3, the temperature of which may be controlled, for example, by a thermostat. The supply of the gaseous medium and carbon compound may be on for a period of time to obtain the desired concentrations, and the concentration of the evaporated carbon compound in the air 10 will then gradually decrease to 0 as the plant uses the substance. The diffusion of the carbon compound can be enhanced by air flows.

The flow rate of the gaseous medium introduced through the tank 2 can also be used to control the metering rate of the volatile carbon compound. The evaporation can also be set to the desired level by means of the aforementioned heating. The gaseous medium supplied from a specific source of gaseous medium is preferably another plant growth promoter, most commonly carbon dioxide. Thus, it is possible to adjust the supply of carbon dioxide and the supply of volatile organic carbon to a certain proportion, e.g. by means of the above-mentioned heating or by otherwise influencing the conditions.

The carbon compound may be evaporated in appropriate proportions to the medium flow at appropriate intervals, depending on the need and growth stage of the plants in the enclosed state 1. In this case, evaporation can be arranged, for example, so that during evaporation, in enclosed space 1, there is no one exposed to the gaseous evaporated carbon compound and the gaseous medium. However, in the case of alcohols, good results can already be obtained with relatively low, harmless alcohol contents of less than 200 ppm.

The process may also be carried out in a continuous evaporation process, whereby in the closed state 1 there is a constant equilibrium concentration of the evaporated carbon compound such as alcohol and a gaseous medium 35 such as carbon dioxide in the air. In this case, the carbon compound is continuously fed in liquid form from a larger tank to an open tank 2, and the tank is prevented from being overfilled by some precautionary measure, e.g. a float. The concentration of the carbon compound can be adjusted to the desired limits by means of a closed, concentration-measuring sensor, 1555439, which adjusts the heating power of the heater 3, for example by adjusting the thermostat of the heater.

A gaseous medium, such as carbon dioxide, is introduced into the liquid volume of the tank 2 from a source separate from the air volume of the greenhouse, such as a carbon dioxide tank known per se, which may be outside the greenhouse or from a combustion process producing carbon dioxide for plants. The source of carbon dioxide can also be inside the greenhouse.

Figure 2 illustrates the arrangement of the VOC feed with the flow of gaseous medium in another way. Here, a known carbon dioxide supply system comprising a pressure vessel 4 and a carbon dioxide supply line, i.e. a flow channel L, is successively provided with a gas heater 5, a pressure relief valve 6 with 15 pressure gauges, a hand valve 7, a flowmeter 1 manifolds 11, which distribute a mixture of carbon dioxide and volatile organic carbon.

The volatile organic carbon compound can be sprayed at some point in the feed line into the CO 2 stream. From the carbon compound reservoir 2, the compound is fed to the CO 2 line L before branching to the manifolds 11, and preferably after the control valve 5. The feeder may be outside or inside the greenhouse and may be of a suitable spraying device or a spraying device arranged to deliver the compound with an adjustable no. at the channel where the carbon dioxide stream flows and which ends in a structure that distributes the mixture of carbon dioxide and carbon compound to the greenhouse. The feeder may also be such that it vaporizes the carbon compound from the reservoir to a gaseous state, after which the gaseous compound is introduced into the carbon dioxide stream. The ratio of carbon dioxide to compound can be desired by adjusting the feed rate of compound ''.

Figure 2 illustrates a system in which one container 4 feeds carbon dioxide slide 35 to a plurality of greenhouses, whereby the line L forks before the greenhouse-specific control valves 5. However, the invention can also be used in supply systems where the supply line L runs from the container only to one greenhouse.

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It is also possible to use another gaseous medium fed from the tank 4 and the arrangements are analogous to those of Figure 2. In addition, it is possible that the container 4 contains the volatile organic carbon compound 5 in liquid form, whereby it as such forms both the source of the gas stream supplying the carbon compound to the confined space and the container of this carbon compound. The carbon compound is evaporated from the reservoir 4 to the feed line, and the adjustment can be carried out according to the same principles as the carbon dioxide supply, with spaces 1 having sensors for measuring the concentration of carbon 10 to be dosed.

If alcohol is used as carbon compound, almost pure alcohol can be used for evaporation with carbon dioxide from tank 2 or tank 4 alone, without having to be separately solubilized in water and handling large volumes of solution. When ethanol is used, it is preferably denatured, provided that the denaturants do not damage the equipment or are harmful to plants at low concentrations.

The method also does not require major modifications to greenhouses where carbon dioxide dispensers already exist.

Practice of methanol administration in the greenhouse for tomatoes, roses and skulls has resulted in a marked increase in growth compared to non-methanol treated plants.

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The results of the experiments conducted on evaporated ethanol are described below.

Till Carbon Fertilization Test 30

Till's carbon fertilizer test was carried out at the Agricultural Production Center's Horticultural Unit in February-March 1998. Till's carbon fertilizer test was based on carbon fertilizer produced by Kekkilä Oy with ethanol concentrations of 20 and 30%. The control was water sprayed on the same amount of control plants as carbon fertilizer for experimental plants. Control plants were shifted to another compartment for 24 hours during injection and to eliminate any possible after-effect. The fourth test member was a so-called odorant kept in the same greenhouse compartment where carbon fertilization was administered, but these individuals were not injected. The purpose was to find out if the carbon fertilizer was transported to the plant from the air.

4 In the pots containing peat, 16 dill seeds were sown. The variety was 5 Bouquet. Plants were exposed to artificial light with high-pressure sodium lamps for 20 hours per day at 180 pmol / m2s light intensity. The temperature was 20 ° C and the carbon dioxide content was 400 ppm. The experiment began when the plants showed their first leaf. Injection treatment was performed once a week. There were four injections. 0.2 ml / L Cito-10 watt was added to the syringe. On the spraying days, the compartment vents were kept closed to prevent volatile carbon fertilizer from escaping too quickly, and the lights were normally on.

Plant analyzes were performed four times. From each pot 12 best 15 plants were selected. One pot was the observation unit. The results thus presented are the sum of the 12 seedlings averaged per test member. There were 10 pots per block and three blocks per test member. The parameters measured were the length in millimeters and the fresh weight and dry weight in grams. In addition, the appearance of the plants, the number of leaves in the spraying and harvesting stages and the condition of the root system were observed.

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The results are shown in graphs 3 to 5. Statistically significantly, the 25 odor members most often differed from the control. The clearest differences were in fresh and dry weights. The differences between the other test members were smaller than before and in most cases were not statistically significant.

30 In appearance, the smell member and control were better looking than the plants that received the ethanol zero spray on their leaves. The spray caused disturbance to the growth of the leaves * and the leaves became dark green. Since the odor member remained intact but superior to control in fresh and dry weights, it can be stated that the odor member was the best of the treatments.

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The number of leaflets did not differ between experimental members at the time of injection and observation.

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Examples of organic volatile carbon compounds are the aforementioned lower aliphatic alcohols, such as those containing 1 to 4 carbon atoms, i.e. methanol, ethanol, propanol and butanol. Other derivatives of organic carbon compounds which are now known to be potent 5 or which subsequently prove to be potent, in particular the C1-C4 apathic hydrocarbons, may be used. The compound should be volatile from a solution, such as an aqueous solution or liquid form, whereby it may be transported in solution, in particular an aqueous solution, or in liquid form, and administered with or without carbon dioxide gas 10 by evaporation from said solution or liquid.

In particular, the simultaneous administration of carbon dioxide and an organic carbon compound produces a good synergy. When alcohols are used, plants have been found to be better at absorbing carbon dioxide at low carbon dioxide levels. Because both substances are administered in gaseous form, green binding plants take them both in the same way, through the lip fractures.

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Claims (12)

105439 A process for improving the growth of plants, wherein the organic carbon compound is evaporated to an appropriate concentration in an enclosed space (1), such as the above-ground parts of plants in a greenhouse, to a suitable concentration in a closed space (1), characterized in that , 4) with a gas stream supplied from its own enclosed space (1) air from a separate gas source. 10 Method according to Claim 1, characterized in that the carbon compound is administered with a flow of other gaseous plant growth promoting material, such as carbon dioxide, fed into the confined space (1). 15 A process according to claim 1 or 2, characterized in that the carbon compound is evaporated from the container containing it with a bubbling gas stream such as carbon dioxide gas. Method according to Claim 1 or 2, characterized in that the carbon compound is administered by feeding it from the container (2) to a gas stream such as a carbon dioxide stream. Process according to Claim 4, characterized in that the carbon compound 25 is evaporated by spraying or atomizing it to a gas stream. Process according to any one of the preceding claims, characterized in that the carbon compound to be administered is an alcohol. 30 An apparatus for improving plant growth comprising a source of volatile organic carbon compound (2) arranged to supply a volatile organic carbon compound to a closed space (1) such as a suitable concentration in a greenhouse, characterized in that the volatile organic carbon compound the source (2) is connected to a gas stream derived from a gas source separate from the air of the enclosed space (1). 105439 8. Apparatus according to claim 7, characterized in that the source (2) of the volatile organic carbon compound is connected to the carbon dioxide supply system of the enclosed space (1). Apparatus according to claim 7 or 8, characterized in that it comprises a gaseous medium, such as a carbon dioxide flow channel, opening into the container (2) containing the carbon compound in liquid or solution form, the feeder being arranged to supply the carbon compound with the gaseous medium. Apparatus according to claim 7 or 8, characterized in that a flow of the carbon compound is derived from the source (2) of the volatile organic carbon compound to a flow channel (L) of a gaseous medium, such as carbon dioxide. 15 11. Apparatus according to claim 10, characterized in that the flow of the carbon compound is connected via a spraying or atomizing device to a flow channel (L) of a gaseous medium such as carbon dioxide. An agent for improving plant growth, wherein the agent is for administration to plants in gaseous form and contains a volatile organic carbon compound, characterized in that the substance comprises a mixture of carbon dioxide and a volatile organic carbon compound, such as alcohol. r i 105439