NL9201631A - Method and apparatus for disinfecting drain water - Google Patents

Abstract

Method of disinfecting drain water, in particular from horticultural enterprises, characterized in that the drain water is admixed with a (preferably aliphatic) percarboxylic acid (preferably peracetic acid), preferably from 0.07 to 0.30 mol of percarboxylic acid being added per m3 of drain water, and in that the drain water is preferably subjected (for from 15 to 60 minutes) to UVC radiation, the dose being preferably in the range of from 700 to 2000 J/l of drain water.

Description

METHOD AND APPARATUS FOR DISINFECTING DRAIN WATER

The invention relates to a method for disinfecting drain water, in particular of horticultural companies. In modern horticultural businesses, plants are grown while they are rooted in an artificial medium, such as rock wool. This medium is irrigated with nutrient solution (i.e. water, in which necessary nutrient elements are dissolved), for example by dripping a nutrient solution on the medium. The nutrient solution contains essential ingredients for plants, such as the nutrient elements NH4 +, K +, Ca ++, Mg ++, H2PO4 ", SO4", Fe ++, Mn ++, Zn ++, B +++, Cu ++ and Mo ++.

To provide the plants with the necessary water and nutrients, an excess of nutrient solution is continuously added. The surplus nutrient solution is collected in drainage channels and collected as so-called "drain water" in a collecting vessel, after which it can be recycled to plant beds after addition of fresh water, preferably rainwater, and nutrient elements. , such as bacteria, fungi and viruses, spread over the entire crop and cause massive damage, therefore the drain water must be disinfected before it is recycled.

This disinfection can be performed in various ways. Firstly, using ozone (03). The drawback of this method is that separate ozone generators are required, while, moreover, provisions are required to dry the gas from which the ozone is generated, to inject and keep gas in the drain water, and to destroy ozone residues.

Secondly, by heating. This has the drawbacks that combustion gases are classified as environmentally polluting (NOx), that heat exchangers are required for heat recovery and that energy consumption is high.

Installations based on disinfection using ozone and / or heating also have the disadvantage that they are expensive.

Thirdly, by adding iodine (J2). This has the disadvantage that viruses in the drain water are not killed.

Fourth, using UVC radiation, where the drain water is passed along UVC tubes. In horticulture, this only works if the drain water is mixed with fresh water.

Applicant has now found that the drawbacks of the prior art disinfection methods can be overcome by adding percarboxylic acid to the drain water instead of 03, J2, UVC radiation or heat.

The invention therefore relates to a method for disinfecting drain water, in particular of horticultural companies, characterized in that a percarboxylic acid is added to the drain water.

Examples of eligible percarboxylic acids for addition are aliphatic and aromatic percarboxylic acids, such as peracetic acid (CH3CO (0) OH), perpropionic acid (C2H5C0 (0) 0H), perbutyric acid (C3H7CO (0) OH) and perbene - zoic acid (C6H5C0 (0) 0H). Since aliphatic percarboxylic acids are likely to be less environmentally harmful than aromatic, the former is preferred. Of the aliphatic percarboxylic acids, peracetic acid is most preferred, since it has no adverse environmental effects, such as, for example, unpleasant odor at all. The amount in which the percarboxylic acid is added to the drain water can vary within wide limits. At too low a concentration, however, the disinfecting effect will be too low, while too high a concentration can have a detrimental effect on the plants when the drain water is recycled.

The preferably added amount of percarboxylic acid is therefore in the range of 0.07 to 0.30 moles per m3 of drain water.

For killing the germs in the drain water, it is not only the concentration of the percarboxylic acid that is important, but also the time during which the germs are in contact with the percarboxylic acid. Therefore, the drain water after addition of the percarboxylic acid is preferably collected in a reaction vessel and left to stand therein for 15 to 60 minutes. The drain water can also first be collected in the reaction vessel and then the percarboxylic acid can also be added thereto. In this case, the reaction vessel is advantageously provided with a stirrer. The killing of the germs by means of the percarboxylic acid in the drain water preferably takes place at ambient temperature. If the environment is too cold, the drain water can be heated, preferably to a temperature of no more than 40 ° C. Due to the addition of percarboxylic acid to the drain water, all germs are completely killed over time. However, germs from bacteria are killed faster and more completely than fungi and viruses.

To also quickly and completely eliminate fungi and viruses, the drain water is preferably also subjected to a treatment with UVC radiation. UVC radiation is electromagnetic radiation in the far ultra-violet region, with a wavelength of 200-280 nanometers. The radiation treatment can take place before or after the percarboxylic acid has been added to the drain water. Since the percarboxylic acid is very capable of eliminating the majority of the germs, it is preferable to first feed the percarboxylic acid to the drain water and then subject it to the UVC radiation treatment. The dose of UVC irradiation is preferably between 700 and 2000 J / l drain water during the radiation treatment of the drain water. At a low UVC dose, the treatment has too little effect and therefore too few germs are killed. Too much UVC radiation causes unnecessarily high energy consumption and installation costs in the present method. Not only the intensity of the UVC radiation is important for the germicidal effect. The length of time during which the drain water is irradiated also plays a major role. It has been found that this time should preferably be in the range of 15 to 60 minutes to obtain a completely disinfected liquid.

The purpose of the present decontamination treatment is to convert the drain water into an irrigation fluid component which is so sterile that it cannot cause disease (s) upon recirculation to the plant material. In order to obtain the final irrigation liquid or nutrient liquid, the disinfected drain water is mixed with fresh water, preferably rainwater, and plant nutrients. This mixing can now be carried out in such a way that the disinfected drain water is first mixed with fresh (rain) water and then with nutrients. If this is the case, after the germs have at least partly been killed by means of a percarboxylic acid, the drain water can first be mixed with fresh (rain) water and then treated with UVC radiation. The latter, because the salts present in the drain water absorb UVC radiation, so that this radiation penetrates into the drain water less deeply than desired and thus has less effect. The addition of (rain) water, which has a very low salt content, improves the disinfection effect of the UVC radiation. The amount of fresh (rain) water with which the drain water is mixed before being recycled to the plant material depends on the water uptake of the plants and any evaporation losses during the recirculation process. This quantity can vary within wide limits and lies in the range from 0.5 to 10 m3 (rain) water per m3 drain water, in practice the range from 1.5 to 3 m3 (rain) water per m3 drain water is advantageously chosen. . As a result of its contact with the plant material and with the substrate in which the latter is rooted, the drain water can contain solid particles. These are preferably removed from the drain water before it is subjected to the present disinfection treatment. This removal can take place in any suitable manner, such as by settling, filtration, centrifugation, etc. A sand filter is advantageously used for this purpose. It is preferable not to mix the drain water with rainwater during the UVC treatment: a larger volume of drain water per unit of time can then be disinfected.

The invention also relates to a device for the above-described method. Such a device comprises the following components connected by pipes: 1. A buffer vessel for untreated drain water.

2. A filling pump for the supply of drain water to a reaction vessel.

3. A dosing pump for the supply of percarboxylic acid solution to the drain water.

4. A reaction vessel for killing germs in the drain water.

5. A buffer vessel for treated drain water.

Preferably, the device according to the present invention additionally comprises the following components: 1. One or more UVC tubes for irradiating the drain water or the mixture of drain water and supplemented (rain) water.

2. A device for removing solid particles from the drain water, preferably a sand filter.

The invention will now be further elucidated on the basis of the following schematic figure description to which the invention is by no means limited. Valves, expansion vessels, measuring and control equipment are not included in this figure. Untreated drain water is fed from a horticultural company (not shown) via a pipe 1 to a buffer tank 2. The drain water is led from the buffer vessel 2 by means of a pipe 3, a filling pump 4 and a pipe 5 to a sand filter 6, in which solid particles are removed from the drain water. The drain water is drained from the filter 6 via a pipe 7. A percarboxylic acid solution is injected into the drain water via a pipe 8, by means of a dosing pump 9 and via a pipe 10, to the drain water.

The mixture of drain water and percarboxylic acid solution is fed via a line 11 to a reaction vessel 12 in which the drain water is at least partially disinfected. The drain water is discharged from the reaction vessel via a pipe 13 by means of a pump 15.

It is mixed with fresh rainwater supplied via a pipe 14, after which the mixture of drain and rainwater is passed through one or more UVC tubes. As the mixture flows through the tubes 16, it is almost completely disinfected by the UVC radiation which is processed in the tubes 16. The mixture is drained through a line 17 to buffer vessel 18 for treated drain water plus fresh make-up water and recycled through a line 19 to the plant substrates (not shown). A solution of plant nutrients can optionally be supplied to the buffer vessel 18 or the line 19.

When not mixed with rainwater, the drain water can be circulated over the UVC tubes to the reaction vessel. The mixing of the drain water with rain water only takes place when the nutrient solution is prepared.

Example

The bacteria Escherichia coli and Pseudomonas sps and the fungus Fusarium oxysporum were added to drain water from the cultivation of roses. The concentration of the bacteria and the fungus were 100,000 and 10,000 per ml, respectively. Furthermore, the drain water contained the nutrients listed in Table I below.

Table I

Main elements Concentration (mmol / 1) NH4 + 1.25 K + 5.00

Ca ++ 3.50

Mg ++ 0.75 NO3 "11.00 H2PO4" 1.25 SO4 1.25

Trace elements concentration (micromol / 1)

Fe ++ 25.0

Mn ++ 5.0

Zw ++ 3.5 B +++ 20.0

Cu ++ 0.75

Mo ++ 0.50

A load of 2.2 m3 of drain water with the aforementioned composition was treated with the method according to the invention in a device as schematically shown in the figure. For this purpose, it was pumped from vessel 2 via pump 4 over sand filter 6 to reaction vessel 12, while with pump 9 it was 200 ml. peracetic acid solution with a concentration of 66 g / l was injected into it, all this per m3 of drain water. In the reaction vessel 12, the mixture was allowed to react for 1 hour. At the same time, the mixture was passed over four UVC tubes with a power consumption of 55W each. The UVC dose was 770 J / l drain water, while the treatment time was 60 minutes. Samples have been taken whose germ count has been determined. The treated drain water was collected in buffer vessel 18 from where it was returned to the plant substrates after the necessary nutrients plus rainwater were supplemented. The reaction product of the peracetic acid (acetic acid) was found to be harmless to the plants. The killing of the bacteria and the fungus using only the peracetic acid (PAA) treatment on the one hand and using the combined PAA-UVC treatment on the other is reported in Table II below.

Table II

Effect of the disinfection treatments

* The kill is expressed as a percentage of the original number of germs added to the drain water.

It can be seen from Table II that with the aid of the method according to the invention a practically complete disinfection of the drain water from horticultural companies can be obtained, all this well within the applied treatment time. As a remarkable result, it has also been established that the UVC transmission rate increased from 35% at the beginning to 50% at the end of the treatment. UVC transmission is measured at 254 nm.

In a method and device according to the invention fungi can grow at the percarboxylic acid concentration used, which can cause blockages. A deposit may also form on the so-called quartz glass of the UVC tubes. These drawbacks can be overcome by - as will be explained below - using a dead amount of drain water present in the installation, i.e. by using that part of the drain water that always remains in the reaction vessel, which in practice amounts to about 10% of the net treated amount of drain water.

The fungal growth can be controlled by introducing percarboxylic acid into the reaction vessel before the actual disinfection of the drain water is started, and then acidifying the mixture of drain water and percarboxylic acid with water to a pH of 1.5 to 2.5 , thus forming (residual water). The residual water is then pumped or stirred for some time, also along the UVC tubes, whereby the acidic water dissolves the deposits on the quartz tubes. This cleaning cycle can be performed every 5 to 40 actual disinfection cycles for 5 to 30 minutes. When a cleaning cycle has ended, an actual disinfection cycle can be started, by filling the reaction vessel with drain water. It is noted that percarboxylic acid no longer needs to be added. The amount of percarboxylic acid used for disinfection corresponds to that of a cleaning cycle.

Claims (15)

A method for disinfecting drain water, in particular horticultural companies, characterized in that a percarboxylic acid is added to the drain water. Process according to claim 1, characterized in that an aliphatic percarboxylic acid is added. Process according to claims 1 and 2, characterized in that peracetic acid is added. Method according to one or more of the preceding claims, characterized in that 0.07 to 0.30 moles percarboxylic acid per m3 drain water are added. Method according to one or more of the preceding claims, characterized in that the drain water is subjected to UVC radiation. A method according to claim 5, characterized in that the drain water is subjected to UVC radiation after the percarboxylic acid has been added to it. Method according to claim 5 or 6, characterized in that during the irradiation the UVC dose is in the range of 700 to 2000 J / l drain water. Method according to one or more of claims 5-7, characterized in that the duration of the irradiation is in the range of 15 to 60 minutes. Method according to one or more of claims 1 to 8, characterized in that a cleaning liquid containing drain water and percarboxylic acid is circulated during (a cleaning cycle of) 5 to 30 minutes, all this after each disinfection (disinfection cycles) of 5 to 40 times. the drain water. Method according to one or more of the preceding claims, characterized in that solid particles are removed from the drain water before disinfection. Method according to claim 10, characterized in that the solid particles are removed using a sand filter. Device for carrying out the method according to claim 1-ll, characterized in that the device comprises the following parts connected by pipes: a buffer vessel for untreated drain water, a filling pump for supplying drain water to a reaction vessel, a dosing pump for the supply of percarboxylic acid solution to the drain water, a reaction vessel for killing germs in the drain water, a buffer vessel for treated drain water. Device according to claim 12, characterized in that it additionally contains one or more UVC tubes for irradiating the drain water. Device according to claim 12 or 13, characterized in that it additionally comprises a device for removing solid particles from the drain water. Device according to claim 14, characterized in that the device for removing solid particles is a sand filter.