NO143214B - PROCEDURE TO REDUCE AIR POLLUTANEOUS ODOR FROM ORGANIC WASTE PRODUCTS - Google Patents

Description

The present invention relates to a new method

to reduce air polluting odors emanating from organic waste products, including organic waste products that are stored to undergo chemical or microbial de-

building, and a new solution for use in the method.

Methods of elimination have been proposed

odors from organic waste products. But such methods have not been entirely satisfactory. In the treatment of human waste products, it has e.g. been used sanitary

products, solids or sanitary liquids. Their main

purpose is to provide a bacteriostatic effect. Usually they act as disinfectants. In reality, providing

they bring an odor-concealing effect when using such aromatic substances as phenolic compounds, camphor, isobornyl-

acetate etc. and the effect is usually temporary.

Different methods have been proposed to reduce the smell in waste products from animals on fields where, for example, is spread manure. It has been proposed in large measure

cane to expose animal waste to the air,

but this air treatment has not been satisfactory due to the low threshold values of certain of the most odorous

bonds. The threshold values or minimum identifiable odor (M.I.O.) in mg/l in air for mercaptans are in the range between 10

-10 -R -9

and 3 x 10 , for dialkyl sulfides from about 10 to 2.5 x 10 ,

for hydrogen sulphide at about 10 _ Q and for skatole at about 1.2 x 10<-8>.

Another method that has been proposed uses deep-level injection of liquid or liquefied fertilizer into the soil. This method produces less odor in the surrounding

lying fields, but not in the crop areas. In Sweden, the aforementioned method was used to reduce odors caused by animal waste on farms that breed pigs.

The best results, although not entirely satisfactory, have been obtained by the use of ammonium persulphate. But even though unrealistically large quantities of this chemical have been used, odors have still not been eliminated or reduced.

serted completely. Furthermore, the chemical does not attack sulphur-

carrier chemicals. The effect of ammonium persulphate has been investigated by others, and the results have been that although the odor intensity was reduced, it was still not satisfactory.

So far, there have been no satisfactory proposals to reduce bad odors from organic industrial wastes, not even from sludge originating from sewage plants.

An attempt to hide the smell from sewage sludge was, for example, unsuccessful.

Many organic waste products are produced daily in large quantities, e.g. on farms that breed animals on a large scale, in waste water from the food industry, in waste products from slaughterhouses, sewage water and sewage sludge, among other things. In these situations, the bad smell is considered a social nuisance and a health hazard, especially in cases where the waste products are stored for relatively long periods of time, such as e.g. with fertilizers and certain soil improvement products.

It is thus an object of the invention to provide an odor-removing or odor-reducing solution using chemicals that are not usually harmful to the environment and that do not significantly affect the chemical or biological processes that are usually used in the further treatment of organic waste products in a harmful way.

Another purpose of the invention is to enable an ecological recycling of organic waste products without the attendant disadvantages of bad smells.

In accordance with these purposes, the present invention is directed to the treatment of waste products from humans and animals originating from metabolic processes, and also to the treatment of organic industrial waste products and waste water.

According to the invention, a method is provided for reducing air polluting odors that come from organic waste products formed by metabolic processes and from organic industrial waste products including wastewater, and the method is characterized by bringing organic waste products into contact with an aqueous sulfuric acid solution containing an oxidizing agent selected from the group consisting of water - soluble

persulfates, nitrates, chlorates and permanganates of ammonium and alkali metals, and a precipitant selected from the group consisting of ferric sulfate and ferric chloride and hydrates thereof, and then maintaining the contact until the odor has been substantially removed.

The use of the aforementioned solution results in simultaneous reactions which involve acidification and oxidation of the waste product and also in the precipitation of odorless and insoluble sulphides. The chemicals chosen are those with sufficient solubility in cold water and which are essentially harmless to the environment.

The amount of acid used should be such that

is sure to achieve a pH value of less than 5, and preferably less than 4, in the treated waste product. If the pH value rises during treatment, more acid can be added.

To transfer such odor-producing chemicals as hydrogen sulfide and organic sulfur compounds to. precipitates,

is iron(II) sulfate and. iron(III) chlorides the most effective.

To obtain the results according to the invention, each reactant must be present. E.g. neither acidification alone, oxidation alone nor sulphide precipitation alone will remove the odors to a sufficient extent. The good results are obtained when all three reactants are used together.

According to the invention, a deodorizing solution is also provided for use in the method. The solution is characterized in that it comprises an aqueous sulfuric acid solution containing an oxidising agent consisting of water-soluble persulphates, nitrates, chlorates and/or permanganates of ammonium and/or alkali metals, and a precipitating agent consisting of iron sulphate or iron chloride or hydrates thereof.

Complete analysis of odorous compounds originating from organic waste materials is not available in the literature. The nature, and also the quantity, of odor-forming compounds depends on the origin of the organic waste substances and on the conditions and duration of storage. The above has a considerable influence on the formation of smelly decomposition products.

In terms of experience, I have observed some chemical properties that are typical for certain types of organic waste. E.g. develops proteinaceous wastes that contain relatively more sulfur and nitrogen, stronger smelling compounds and more ammonia. This is especially the case with organic waste substances formed

by metabolic processes. Among other by-products, these waste products contain urea, which is immediately broken down by enzymes to form ammonia.

The chemical requirements for removing odors from certain waste products are summarized below as an example.

Human waste is treated with approx

50 to 100 mg oxygen/kg waste (850-950 ml) and animal waste with around 190 to 205 mg oxygen/litre waste. With regard to organic industrial waste products, no average figures are available because such waste products tend to have varying compositions. The chemical requirements for sewage water are usually in the range from around 8 to 10 mg oxygen/l, while for sewage sludge (e.g. excess sludge) around 17 to 21 mg oxygen/l (litre) is required.

With regard to the use of iron salts as precipitants, about 112 to 180 mg Fe/kg (850-

950 ml) waste product for human waste products,

about 150 to 200 mg Fe/l for waste products from animals, about 30 to 35 rag Fe/l for sewage water and about 12 to 30 mg Fe/l for sewage sludge.

The need for acid, expressed as sulfuric acid, is as follows: about 3.35 to 3.37 g/kg (850-950 ml) of waste product for human waste products, about 7.9 to 13 g/l for animal waste products, about 0 .23 to 0.30 g/l for sewage water and about 0.13 to 0.17 g/l for sewage sludge.

The aforementioned requirements are met with deodorized aqueous compositions containing the following amounts of reactants, based on mg/g solution, when used for certain waste products:

In certain cases, further acid can be added to the waste product after treatment with the deodorising compositions.

Organic waste products containing phosphates, so

such as excess sludge from sewage post-sweeping treatment systems, can be treated with solutions containing sufficient iron(2) or iron(3) compounds to effect removal of the phosphorus by sweeping and to remove odors.

The following are examples of solution compositions

for the treatment of waste products, which compositions are provided according to the invention:

The sulfuric acid is added to water and is followed by the other ingredients. The final solution has a density at 20°C (d2Q) of 1.370. The total weight of the solution is about 1000 kg, and the solution contains 12.01 HgSO^, 25.0% iron(2) sulfate, 6.2% sodium chlorate and the rest is about 56.8% water.

The sulfuric acid is added last to the solution, and the solution

has a density (c^o^ of 1>333- The total weight of the solution is about 1000 kg, and it contains 28% iron(3) chloride hexahydrate, 8.5% ammonium nitrate, 17% sulfuric acid and the rest is essentially 46.5% water.

The sulfuric acid is added to the water followed successively by ferric sulfate and sodium chlorate to form a solution having a density (d2Q) of 1.282. The weight of the solution is about 1000 kg, and it contains 4% I^SO^, 30% iron(2)-sulphate, 9% sodium chlorate, and the rest is about 57% water.

The sulfuric acid is added to the water successively followed by ferrous sulfate and ammonium chlorate to form a solution with a density (dgg) of 1.351. The weight of the solution is about 1000 kg, and it contains 4% sulfuric acid, 35.1% crystallized iron(2) sulfate, 10.5% ammonium chlorate, and the rest is about 49.8% water.

The sulfuric acid is added last to the solution, which has a density C^q) p^ 1»335- The total weight of the solution is about 1000 kg, and it contains 28% iron(3) chloride hexahydrate, 9.5% sodium nitrate , 17.0% HgSO^, and the rest is about 45.5% water.

It should be understood that reference to crystallized iron(2) sulfate means the heptahydrate, while reference to iron(3) chloride means the hexahydrate.

As illustrations of the use of solutions of the preceding type when removing odors from organic waste products, the following examples are given:

Example 1

When treating waste products from pigs, 3 kg of an odor-removing solution is added per cubic meters of waste product, and in said solution 25% by weight of crystallized iron(2)-sulphate, 15% sodium chlorate, 6% sulfuric acid are dissolved, and the remainder is substantially 54% water. To be sure to obtain a satisfactory pH value in the final mixture, a further 3 kg of sulfuric acid is added to the pig waste products. The smell of the waste products from pigs instantly became weaker, and

after a day it was essentially eliminated.

The soluble reaction products comprise 246 mg of sodium chloride and 4.5 kg of ammonium sulphate per cubic meters.

Example 2

Waste products from pigs are treated with 3.5 kg of an odor-removing solution per cubic meter of waste product, and the solution contains 30% by weight of crystallized iron(2)-sulphate, 12.3% by weight of sodium chlorate, 5.5% by weight of sulfuric acid, and the remainder is essentially 52.2% by weight of water. The pH value in the waste products is further adjusted by adding 2.8 kg of sulfuric acid. The results obtained are the same as for example 1.

The soluble reaction products include about

239 mg/l with sodium chloride and around 3.9 kg of ammonium sulphate per cubic meters.

Example 3

To 1000 kg of waste products from humans, 2 kg of a deodorized solution according to example B is added, which contains 28% iron(3)-chloride hexahydrate, 8.5% ammonium nitrate, 17% sulfuric acid and a residue of substantial 46.5% water. The smell was immediately weakened, and this was long-lasting. There was again a faint smell of garden compost.

The soluble products formed include about 138

mg N02/kg (850-950 ml), around 458 mg ammonium sulphate per kg and around 856 mg ammonium chloride per kg.

Example 4

When treating waste products from people in an unflushed caravan toilet, about 10 g of solution is added per individual per day. The solution contains 14% by weight of iron(3) chloride, 4.3% by weight of ammonium nitrate, 8.5% by weight of sulfuric acid, and the remainder is essentially 73.2% by weight of water.

The soluble reaction products comprise about 244 mg N02/kg, about 800 mg ammonium sulfate/kg and about 1.5 g ammonium chloride/kg.

Example 5

Surplus sludge from a post-precipitation treatment of sewage is treated by adding 0.75 kg of solution per cubic meters thereof, and where the solution is in accordance with the composition in example A, which contains about 26.7% crystallized iron(2)-sulphate, about 6.6% sodium chlorate, about 12.7% H2SO^ and the remainder essentially 54% water. The repulsive

the smell was immediately reduced to a faint smell of mold. This odor lasted until at least the dewatering and concentration steps. The last steps were eased due to a marked reduction in the sedimentation time and increase in the final solids content. The preceding operation was carried out continuously for 6 weeks at a flow rate of 35 to 45 liters of excess sludge per second.

The soluble reaction products included about 25 mg/l with sodium chloride and about 120 mg/l with ammonium sulfate (87 mg/l soc).

Example 6

An odor-removing solution corresponding to example C is added to excess sludge from a treatment system for the post-sweeping of sewage water in an amount of about 0.5 kg per cubic meters. The solution contains 30% dissolved crystallized iron(2) sulfate,

9% sodium chlorate, 4% sulfuric acid and essentially 57% water. The results obtained are similar to the results from example 5. After adding the solution, the pH value was adjusted to below 5 by adding 80 g of sulfuric acid per cubic meters of waste material.

The soluble reaction products include about 25 mg/l with sodium chloride and about 126 mg/l with ammonium sulfate (92 mg/l with SOjj).

Example 7

Surplus sludge from a treatment system for post-sweeping sewage is treated by adding 0.5 kg of deodorizing solution per cubic meter of waste material, and the solution comprises 35% dissolved crystallized iron(2)-suKat, 7.6% sodium chlorate, 4% sulfuric acid and a remainder of essentially 53.4% water. After the addition of the solution, the pH value was further adjusted by adding 90 g of sulfuric acid per cubic meter of waste material. The results obtained correspond to those obtained in examples 5 and 6.

The soluble reaction products include about 21 mg/l with sodium chloride and about 138 mg/l with ammonium sulfate (101 mg/l with SOjj).

Example 8

Sewage water that has previously been treated mechanically to remove coarse solids was exposed to the method according to the invention by adding 0.4 kg of deodorizing solution per cubic meters of said sewage water. The solution contains 30 percent by weight dissolved crystallized iron(2) sulfate, 9% sodium chlorate, 4% sulfuric acid and essentially 57% water. After the addition of the solution, the pH value in the mixture was adjusted by a further addition of 195 g of sulfuric acid per cubic meters. The smell was immediately eliminated, and spontaneous flocculation and sedimentation took place. Around 90% of the original phosphorus had been removed.

The soluble reaction products include about 19.6

mg/l with sodium chloride and about 267 mg/l with ammonium sulfate (194 mg/l with SO^).

As will be clear from the previous examples, the composition of the deodorizing solution can be varied over a relatively wide range. The solution may thus comprise about 3 to 25 percent by weight of sulfuric acid, about 3 to 20 percent by weight of an oxidizing agent from the group consisting of sodium chlorate and ammonium nitrate, about 10 to 40 percent by weight of an iron salt from the group that includes hydrates of iron (2) sulfate and iron ( 3) chloride and the remainder of about 40% by weight water.

Claims (5)

1. Procedure for reducing air polluting odors that come from organic waste products formed by metabolic processes and from organic industrial waste products including wastewater, by oxidation in a weakly acidic environment, precipitation of insoluble sulfur compounds and neutralization of ammonia and amines, characterized by bringing the organic waste products into contact with an aqueous, sulfuric acid solution containing an oxidizing agent consisting of water-soluble persulphates, nitrates, chlorates and/or permanganates of ammonium and/or alkali metals, and at the same time with a precipitating agent consisting of iron sulphate or iron chloride or hydrates thereof, and then the contact is maintained until the smell has essentially been removed. 2. Method according to claim 1, characterized in that an aqueous, acidic solution is used which contains 3 to 25% by weight of sulfuric acid, 3 to 20% by weight of an oxidizing agent from the group of sodium chlorate and ammonium nitrate, 10 to 40% by weight of iron (II) -sulphate or iron(III) chloride" or hydrates thereof, and a residue which makes up at least 40% by weight of water. '3. ' - Method according to claim 1, characterized in that the pH value in the solution which is in contact with the organic waste product is adjusted to below 5. 4. Deodorizing solution for use in the method according to claim 1, characterized in that the solution comprises an aqueous sulfuric acid solution containing an oxidizing agent consisting of water-soluble persulfates, nitrates, chlorates and/or permanganates of ammonium and/or alkali metals and a precipitating agent consisting of ferrous sulfate or ferric chloride or hydrates thereof. 5. Solution according to claim 4, characterized in that the aqueous solution contains 3 to 25% by weight of sulfuric acid, 3 to 20% by weight of an oxidizing agent from the group of sodium chlorate and ammonium nitrate, 10 to 40% by weight of iron (II) sulphate or iron (III) chloride or hydrates thereof, and a remainder which constitutes at least 40% by weight of water.