DE1817983C2 - Agent for cleaning the boiler on the furnace side by breaking off the combustion residues - Google Patents

Description

Alkylbenzenesulfonate 12.0 parts
Commercial ammonium

bicarbonate / carbonate mixture 15.0 parts

Ammonium phosphate 2.0 parts

Ammonium nitrate 6.0 parts

water

ad 100.0 parts

The invention relates to a means for cleaning the boiler on the furnace side by blasting off the combustion residues by treatment with aqueous solutions of a mixture of compounds which decompose thermally into gases.

It is well known that fuels (e.g. coal, coke or oil) form inside boilers solid residues, which consist partly of soot and tar, partly of non-combustible, inorganic ash residues. Such deposits build up in the form of firmly adhering deposits on the boiler walls or the heat exchanger elements and hinder due to their strong thermal insulation properties the heat transfer. They also lead (due to the content of inorganic ash residues, z. B. acidic sulfur compounds) also to corrosion on the metallic inner parts of the Boiler. The regular removal of such residues is therefore essential.

The removal of such deposits has hitherto generally been done mechanically, i. E. H. by Knocking, scrubbing and scraping, with the cleaning and rinsing effect of aqueous alkaline solutions was exploited. It is also already known to have such aqueous alkaline solutions in the interior of the boiler to be sprayed under pressure using a special device in order to achieve purely mechanical cleaning make it easier or superfluous (see Swiss patent specification No. 3 60 072).

As usable in the last-mentioned process, alkaline reacting substances are alkali or Alkaline earth salts with anions of weak acids (such as

Soda, sodium bicarbonate, trisodium phosphate etc.) or alkali hydroxides are recommended. Rather high salt concentrations are used. This results in the risk of greater deposition of medium residues which, as a result of subsequent reaction with acidic combustion products, can assume corrosive properties and possibly also store excess acid components.
As practical experience has shown, need

ίο the known processes also have a relatively large amount of water, since the alkaline liquid and the residues are largely removed from the boiler again should.

From French patent 8 63 574 it is known in the pretreatment of metallic workpieces Removal of scale and oxide layers with aqueous solutions, thermally with evolution of gas contain decomposing substances. There are in particular ammonium salts or salts of organic amines

μ oxalic acid described. According to the details of this Patent specification, the quenched, still hot workpiece is immersed in the oxalate solution, whereby the Part of a dissolution of the oxide or backing layer due to the rust and metal oxide removing Properties of the oxalate solution and, in part, a detachment of the layer due to thermal decomposition of the Salt should be effected.

In this immersion process according to French patent specification 8 63 574, only part of the dissolved material penetrates

<o Salt into the highly heated oxide or scale layer and leads to a blast there. A not inconsiderable part of the salt is already decomposing penetration on the hot surface and is thus withdrawn from further action. For this

The reasons are also relatively high salt concentrations of around 5 to 15 percent by weight according to the information this patent is required.

The teaching conveyed in French patent specification 8 63 574 cannot be readily applied to the

»Ο Transfer boiler cleaning. Oxalic acid compounds are highly toxic substances that are subject to the Poison Ordinance. For their handling are accordingly special safety precautions required. The complete decomposition of oxalic acid compounds takes place with the formation of carbon monoxide. When using only oxalate-containing solutions for In the meantime, cleaning the boiler can be expected to have relatively high carbon monoxide concentrations. a circumstance that is particularly important when cleaning combustion systems in closed rooms, because of the risk of damage to the operating personnel deserves special attention.

There are differences between the layers of scale and oxide on the one hand and combustion deposits forming solid deposits on the other hand in that the former are endogenous, i.e. through chemical conversion of the metallic substrate, while the latter are formed exogenously, i.e. through the deposition of substances contained in flue gases. This different type of formation as well as the associated different crystal structure and habit, the crystalline structure, the surface properties, the porosity and the absorption capacity of the coatings adhering to the substrate cause differences in the adhesive strength

μ the strength and hardness of the coverings. In the end The different chemical composition of the coatings is of considerable importance to.

Another difference is that which can be achieved with workpieces and boiler equipment different temperatures. Metallic workpieces can be heated to such a high temperature without difficulty that in the treatment by the immersion process according to the French patent 8 63 574 with an ammonium oxalate solution a complete decomposition in ammonia, carbon dioxide, Carbon monoxide and water enter the boiler walls achievable temperatures are in contrast in general very much lower, since the Walls from the side of the heat transfer medium (water, steam), are constantly cooled. These lower temperatures not only reduce the rate of decomposition, they can in addition also cause a different course of the decomposition reaction. In boiler facilities there is therefore the risk that when using solutions that contain only oxalates z. B. ammonium oxalate contain an incomplete decomposition of the salt into ammonia and non-volatile oxalic acid The strongly acidic oxalic acid precipitating on the metal walls behaves as is well known aggressive towards metals and causes signs of corrosion there. To face this danger If only oxalate-containing solutions were used, it would therefore be essential to use the furnace rinse thoroughly with water after cleaning.

From all of this it follows that the use is described in French patent 8 63 574 Oxalate solutions - even after adding a wetting agent - have disadvantages when cleaning boiler systems and in addition, unsatisfactory results can be expected is

BE-PS 5 18 666 describes a "· " experience, which consists in the action of an aqueous or gaseous mixture of carbon dioxide, ammonia and water or using an aqueous one. Solution containing ammonium carbonate or ammonium bicarbonate, to soften and remove acidic deposits on the combustion side of boilers by neutralization. Concentrations are not given. Because of the aforementioned high heat release which occurs during the neutralization of the acidic deposits, it must be assumed that only relatively high concentrations of the active ingredient could be regarded as promising in the context of this technical teaching.

The US patent specification 24 19 076 gives the teaching to remove carbon-containing deposits in boilers with gas-evolving solutions. With these Prior art methods are first of all impregnated with an acid and the carbonaceous coverings then an inorganic carbonate or hydrogen carbonate solution is sprayed on Carbon dioxide is said to cause the deposits to explode. This type of boiler cleaning has several disadvantages. According to the teaching of the US patent is a two-component system required for cleaning. The individual solutions must be handled strictly separately before use will. The one used in this procedure Acid attacks the metal parts of the furnace, so care must be taken that it neutralized or otherwise removed as quickly as possible. The impregnation with acid and the self subsequent treatment with carbonate-containing solutions must therefore take place in quick succession. Even if the carbonate or hydrogen carbonate solution in excess is applied, can not be ruled out with certainty that not inaccessible Acid residues remain in the heating system. Salt solutions are also used in this process or salts are formed which have to be removed separately after cleaning. Gas evolution also occurs when applying the carbonate or hydrogen carbonate solution already wetted with acid Surface of the carbonaceous deposits. The gas bubbles that form in the process prevent penetration the carbonate solution into the acid-filled pores and crevices of the deposits. The gas development occurs therefore mainly on the surface or the upper layers of the deposits. The effectiveness of the This means that the residues are severely impaired because only a very small part of the gas is released is formed inside the residue mass.

The object of the present invention was to eliminate the disadvantages described above through use a solution that

1. a high network and penetration effect,

2. a good neutralizing effect,

3. a strong evolution of gas at elevated temperature and

4. Has little residue build-up.

This object is achieved by a means for cleaning the boiler on the furnace side by blasting it off the combustion residues by treatment with aqueous solutions of a mixture of thermal in gases, preferably carbon dioxide and ammonia decomposing compounds, which is characterized is that it is 0.1 to 4 percent by weight of the mixture which largely decomposes with evolution of gas and 0.1 to 4 percent by weight of conventional anionic, amphoteric or nonionic surfactants in aqueous Solution contains.

The compounds which decompose thermally with evolution of gas are preferably Substances that decompose with the development of ammonia, as this provides the desired neutralization effect is most easily achieved. Particularly preferred are compounds which are thermally in ammonia and carbon dioxide decompose, such as ammonium carbonate, ammonium bicarbonate, ammonium carbamate or urea. However, it is also possible to use compounds in a mixture which, in addition to or instead of the gases mentioned, other gases develop such as ammonium oxalate, ammonium formate or Ammonium nitrite. However, these last-mentioned compounds only play a subordinate role; she are not the main component of the mixture of compounds, but are at best used alongside or in conjunction with used in substances that break down ammonia and carbon dioxide.

In principle, such gas-evolving substances can also be used in a mixture, if desired find that do not develop ammonia, e.g. B. Compounds used as blowing agents for manufacture Serve from artificial foams. These are to substances that split off nitrogen at elevated temperatures such. B. azodicarbonamide, azobutyric acid nitrile or substituted thiotriazoles. Oxygen-evolving compounds, such as. B. urea peroxy adduct come into consideration insofar as they are durable in addition to the other components of the cleaning agent

are. If these substances are sparingly or not at all soluble in water, they can be in the cleaning agent can also be contained in finely divided form. Such substances are not considered to be gas-evolving alone Component used, but at most to intensify the gas development together with the ammonium salts referred to above.

If substances which do not develop ammonia are used, it may be advisable to add ammonia to achieve a neutralizing effect. In addition, an addition of ammonia can also be used of ammonia-releasing compounds occur when a stronger alkalization is sought will.

It is entirely possible and can be expedient to use different surfactants side by side.

The effectiveness of the agent according to the invention can also be increased by additives that have a to bring about a certain corrosion protection of the treated metal surfaces are suitable, such as ammonium phosphate or zinc phosphate Also additives which, due to their oxidizing effect or a-if catalytic Ways to support the removal of the soot and tar fractions that form the deposits promote the effectiveness of the new means. Such additives are ammonium nitrate or ammonium chromate or copper or Zinc salts (preferably in the form of their ammoniacates) are called. Of course, these additives, as long as they are compatible with one another and with the two obligatory components of the agent according to the invention are also to be present next to each other.

If the agent according to the invention is used, a surfactant content of 0.1 to is usually sufficient 4%, preferably about 0.3 to 0.7%. The content of thermally easily decomposable substances can be in the are of the same order of magnitude. It is therefore much lower than the content of alkaline reactants Substances or substances that decompose with the development of gas in the boiler and surface cleaning agents according to the state of the art. The content of non-obligatory, but beneficial additives can are each below 1%.

However, the agent according to the invention is sold because of the space savings associated therewith expediently in a more concentrated solution, which the user then adjusts to the previously described one Application concentration is to be diluted with water.

The agent can be used to clean the boiler as follows:

The aqueous solution of the above components is diluted to the prescribed level Application concentration sprayed into the boiler, for which a commercially available sprayer is sufficient Performance (such as is offered for the purpose of pest control in the garden) fully enough. The amount to be introduced depends on the strength of the deposits, which are plentiful and should be soaked evenly. Then the heating is put back into operation, whereby with increasing temperature the (mechanically effective) gas evolution of the thermally decomposing substances in A passage comes and causes a plate or shell-shaped chipping and splitting off of the enclosures. At the same time, the acidic deposit components are neutralized and converted into compounds that at higher temperatures - decomposed or undecomposed - are largely volatile. After spraying with water can therefore be reduced to a minimum or even omitted entirely without being detrimental Show effects.

The use of the agent according to the invention has

ίο versus the prior art proposals the advantage that through the first complete soaking of the residues in the subsequent heating, the gas development not only on the surface, but in the entire inner body the residue mass takes place, so that a complete detachment from the metal base is achieved. the subsequent heating does not need to be carried out after the impregnation; necessarily be done immediately and A break can be inserted between the two work steps, for example by an extended one Contact time a better impregnation thicker To achieve deposits.

Another advantage of the agent according to the invention is that it is not only used for boiler cleaning, but also for cleaning vüfi gas-powered heating devices such. B. Gas water heaters can be used. In this type of application the heating device, i. H. the Gas burner, not to be switched off during the treatment and the application of the agent can even with the burner switched on.

The following examples illustrate, in a non-limiting manner, some compositions of the invention By means of:

example 1

Alkylbenzenesulfonate 12.0 parts
Commercial ammonium

bicarbonate-carbonate mixture! 5.0 parts

Ammonium phosphate 2.0 parts

Ammonium nitrate 6.0 parts

Water ad 100.0 parts

When using the concentrate described above is diluted in a ratio of 1:25.

Example 2

Alkyl phenol polyglycol ether 8.0 parts

(Alkyl group e.g. with

8-16 carbon atoms, 8-14 mol
Ethyleno «yd)

Ammonium carbonate, techn. 8.0 parts

Organic ones that split off nitrogen at higher temperatures

Connection, e.g. B. Azobisiso-

butyronhril 6.0 parts

Heavy metal combustion catalyst 6.0 parts
Water ad 100.0 parts

When using the concentrate described above is diluted in a ratio of 1:20.

Claims (4)

Patent claims: 1. Means for cleaning the boiler by blowing off the combustion residues by means of treatment with aqueous solutions of a mixture of thermally in gases, preferably Carbon dioxide and ammonia decomposing compounds, characterized in that that there is 0.1 to 4.0% by weight of the mixture which decomposes with evolution of gas and 0.1 to 4.0% by weight common anionic, amphoteric or nonionic Contains surfactants in aqueous solution 2. Composition according to claim I _1, characterized in that it contains conventional surfactants and thermally decomposing compounds in a concentration of 0.3 to 0.7 wt .-% each 3. Composition according to claim 1, characterized in that there are also corrosion inhibitors and / or contains agents that promote soot or tar combustion. 4. Concentrate for the preparation of the agent according to claim 1 by dilution in a ratio of 1:: 25, characterized in that it has the following composition: