DE202015004960U1 - Active ingredient for the treatment of process water - Google Patents

Abstract

Active substance for the treatment of process water, characterized in that the active substance can be produced by means of electrolysis.

Description

The present invention relates to an active ingredient for the treatment of process water.

Process water can arise, for example, in papermaking. As part of papermaking, cellulose fibers are mixed with aqueous solutions and floated. In this case, a concentrated aqueous slurry of cellulosic material, the so-called pulp, is diluted by the addition of water to thereby obtain a dilute aqueous slurry of cellulosic material.

Starch polysaccharides and their degradation products with a molecular weight of more than 1 × 10 ⁶ g / mol can contribute to a gain in strength in the finished paper.

Investigations have shown that in this type of papermaking significant amounts of starch are transferred to the material resolution. Thus, due to low binding forces up to 70% of the starch in the pulp dissolution in pulp are removed from the fibers with process water. The dissolved starch is also referred to as stray starch. In this case, the so-called stray starch immediately after the dissolution process contains valuable effective components that could be used in papermaking to gain strength.

If the stray starch enters the process water, it is metabolized relatively quickly, so that only a small part of the starch can be retained in the non-woven fabric and only a small strength gain in the finished paper can be achieved. The majority of the starch, however, is discharged with the wastewater.

Starch can be degraded both intracellularly and extracellularly by enzymatic means. This produces starch polysaccharides which may be linear or branched. Further degradation leads to oligosaccharides. In a total hydrolysis, the starch can be degraded to the monomer glucose.

In intracellular metabolism, starch polysaccharides are metabolized within the cells of the microorganisms. As a result, the fragments in the stock suspension are no longer available. If the starch is metabolized in this way, it is no longer available for a development of strength in the finished paper. Instead, additional materials must be added to achieve the desired strength.

Various microorganisms can emit enzymes, such as amylase. By means of these enzymes, starch polysaccharides can be comminuted extracellularly. If the resulting fragments have a molecular weight of less than 1 × 10 ⁶ g / mol, the starch fragments are no longer effective for strength development.

When defibrating the waste paper in pulp, the starch dissolves and pollutes the entire water cycle of the paper mill. The result is COD levels (COD: Chemical Oxygen Demand, a measure of all oxidizable substances present in the water) in the amount of, for example, 5000 to 8000 mg / l, which are predominantly due to starch.

Due to the water temperature and the residence time of the starch in the water, microorganisms in anaerobic environment decompose the starch into low-molecular acids. This causes a pH reduction towards an acidic region. This in turn favors the outgassing of the volatile fatty acids and thus the formation of odor emissions. In addition, the acidic pH causes calcium carbonate to dissolve out of the waste paper. The consequence of this is very high calcium contents in the circulating water and, as a result, a variety of calcification problems, especially in the area of anaerobic and aerobic treatment stages.

The illustrated mechanisms therefore lead to odor formation, corrosion and reduced effectiveness of the chemical additives used in papermaking.

It can be assumed that the major part of the starch that circulates in the paper mill's circulating water will not be bound to the fiber during sheet formation because the starch is neither anionic nor cationically modified. Instead, the starch goes with the white water directly to the sewage treatment plant. The wastewater treatment plants of packaging paper factories must be enormously efficient due to this freight. The power requirement of wastewater treatment plants has been steadily increasing in recent years as the proportion of starch in recovered paper increases more and more.

This underlines the high need in the art to provide active ingredients and processes which ensure that the materials used in the process are optimally fed to the papermaking or strength development of the paper.

This loss of strength described above initially causes a business failure. Instead of the lost starch, components must be added in an extra step to achieve the desired strength.

In addition, the stray and metabolized starch causes increased oxygen demand in process water and wastewater. This leads to a further increase in the cost of wastewater treatment. In addition, the unused stray starch and its breakdown products lead to corrosion, deposition, odor and reduced effectiveness of additives.

In the prior art, agents for preventing the metabolism of the starch are known. That's how it describes WO 2012/025228 A1 a papermaking process using one or more biocides, and additionally adding an ionic polymer and an auxiliary ionic polymer.

The EP 0 361 736 describes a composition containing starch and a flocculant known from papermaking.

However, the methods or compositions known in the prior art have a number of disadvantages.

Thus, the biocides used in the prior art have a negative impact on the environment. As a result, the costs of disposing of the waste water are further increased because the biocide must be removed or must be bound by the addition of other substances.

Against this background, it is an object of the present invention to provide an active substance for the treatment of process water, which overcomes the above-described technical disadvantages of the active compounds available in the prior art.

This object is achieved with the features of claim 1.

Advantageous further and further developments of the invention are the subject of the dependent claims.

The present invention solves the problem described above by the fact that the active ingredient can be produced by means of electrolysis. As a result, a significant improvement over the prior art is achieved.

The active ingredient produced by electrolysis is an aqueous, health-safe active ingredient. Since the active substance is harmless to health, a negative effect on the environment can be ruled out. Additional additional costs caused by the active ingredients available in the prior art are therefore not incurred. The process water, which is treated by means of an active substance that can be produced by electrolysis, can be disposed of via the ordinary wastewater system after processing.

It has proven to be particularly advantageous when the process water is a process water from paper production. Process water from papermaking has a particularly high starch content. By existing microorganisms, the existing starch is metabolized relatively quickly, so that they can contribute only slightly to the strength gain in the finished paper. Most of this metabolized starch is carried away with the wastewater. With the aid of the present invention, it is now possible to suppress or reduce this metabolism of the starch by means of the active substance which can be produced by means of electrolysis. This not only reduces the burden on the environment, but also reduces costs, as the starch that is not metabolized can now contribute to the gain in strength of the finished paper. In addition, negative properties of the degraded starch such as corrosion, deposition or odor and reduced effectiveness of additives are prevented. By less metabolizing the starch, it can be used to achieve the desired mass and surface area. This will improve the efficiency of biomass utilization through innovative usage cascades. The thus saved renewable raw material starch can be used as a consequence for other applications. In addition, the increased use of renewable raw material starch can substitute fossil based synthetic dry strength agents, thus saving drying energy. This will help to reduce CO ₂ emissions.

It has proven to be advantageous if the active ingredient is a disinfecting agent. This ensures the microbiological purity of the process water.

It has also proved to be advantageous if the active ingredient has a pH of 2.0 to 9.5 and a redox potential of +300 to +1200 mV. At this pH or redox potential, the active substance produced by electrolysis has its optimum effect.

It is particularly advantageous if the active ingredient has a pH of 7.

In addition, it has proved to be particularly advantageous if the active substance anolyte, selected from the group of NaOCl, Cl ₂ , HOCl and OCl ^- includes. On the one hand, these anolytes ensure the effectiveness of the active ingredient, but on the other hand they have the advantageous property that they are harmless to the processed substances and to the environment in the concentrations used.

It has proved to be particularly advantageous if the process water has an anolyte content of at most 100 to 600 ppm. In this area, the anolyte of the drug act optimally, but at the same time it is ensured by this area that no negative properties are to be feared on the material to be processed or on the environment.

By way of example, a process for the treatment of process water, for example from papermaking, is disclosed, wherein an aqueous, harmless substance which can be produced by means of electrolysis is added to the process water.

If the process for the treatment of process water from papermaking is used, an economically advantageous, environmentally friendly and resource-saving process for papermaking is achieved.

• a) Aufschließen eines Cellulosematerials, umfassend Stärke;
• b) Behandeln des Cellulosematerials, umfassend Stärke mit einem oder mehreren Wirkstoffen, wobei der Wirkstoff oder die mehreren Wirkstoffe mittels Elektrolyse herstellbar ist/sind.

Also disclosed by way of example is a method for producing paper and / or cardboard and / or cardboard, which comprises the following steps:

• a) digesting a cellulosic material comprising starch;
• b) treating the cellulosic material comprising starch with one or more active ingredients, wherein the active ingredient or the plurality of active ingredients is / are producible by means of electrolysis.

Such a method is suitable for overcoming the disadvantages of the prior art described above.

The following embodiment clearly shows the advantages of the present invention.

In a cooking process shredded wood chips are chemically treated. Through an eleven to twelve hour cooking process, the unwanted wood components are separated. The wood is treated according to the organic cell process developed in Kelheim in Lower Saxony, which is used for the sulfur-free and thus more environmentally friendly pulp production. In several successive cooking operations, the wood chips are digested in a water-methanol mixture with the addition of sodium hydroxide solution at temperatures up to 185 ° C under pressure. Under these conditions lignin and hemicellulose dissolve. This is followed by various washing stages, in which the pulp is freed from the cooking liquid. This is followed by bleaching and dewatering. After boiling in a water-methanol mixture with the addition of sodium hydroxide solution at temperatures of up to 190 ° C under pressure, the resulting solution in which lignin and hemicellulose are located, separated from two batches. The first batch is not treated additionally, whereas the second batch is treated with an active ingredient which can be prepared by electrolysis. This active ingredient is used in a concentration of 100 to 600 ppm anolyte content in the process water. After four days, both solutions are compared. It can be seen that the starch content of the batch treated with the active ingredient produced by electrolysis is 22% higher than the starch content in the untreated batch.

The following embodiment discloses a method for producing the active ingredient.

The electrolysis in a galvanic cell of the cleaning liquid is carried out either in a cell which is divided by a membrane (diaphragm) in the anode and cathode compartment or in a cell which is not separated, so instead of anolyte and catholyte only produces a substance. By carrying out only a weak electric field and by operating the galvanic cell continuously, it is possible that the production of sodium hypochlorite and its forms of dissociation are not the focus of production of caustic soda. As a result, when a sodium chloride solution passes through the chamber, no oxidizing substances such as chlorite, chlorine dioxide and other oxidizing agents are formed; only sodium hypochlorite is formed in small quantities.

Investigation of the disinfecting effect of the galvanized cleaning fluid has shown that the disinfecting effect is equivalent to or better than disinfectants obtained by electrolysis, or classical chemical disinfectants.

The present invention provides a cost-reducing and environmentally friendly way to reduce starch degradation in a process water and thereby make better use of existing starch.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2012/025228 A1 [0016]
• EP 0361736 [0017]

Claims (7)

Active substance for the treatment of process water, characterized in that the active substance can be produced by means of electrolysis. Active ingredient according to claim 1, wherein the process water is a process water from papermaking. Active ingredient according to claim 1, characterized in that it is the active ingredient is a disinfecting agent. Active ingredient according to one of the preceding claims, wherein the active ingredient has a pH of 2.0 to 9.5 and / or a redox potential of +300 to +1200 mV. Active ingredient according to one of the preceding claims, wherein the active substance has a pH of 7.0. Active ingredient according to one of the preceding claims, wherein the active substance comprises anolyte selected from the group NaOCL, Cl ₂ , HOCl and OCl ^- . Active ingredient according to one of the preceding claims, wherein the process water has an anolyte content of at most 100 to 600 ppm.