DE3301799A1 - Oil-dispersible stable metal salt solutions for fuels, and a process for producing them - Google Patents

Abstract

A water-based, oil-dispersible fuel additive is proposed. The fuel additive contains a metal salt solution, the metal salt being selected from the group comprising an alkaline earth metal salt from group IIA of the Periodic Table, a transition metal salt or a metal salt of a Lewis acid, a cationic surfactant, a coupler component and a stabiliser component.

Description

Oil-dispersible stable metal salt solutions for

Fuels and a method for making the same The invention relates to fuel additives for use in large, oil-burning stoves. In particular the invention relates to treatment additives for fuels used for Reduction of corrosion in boilers on the combustion side and in air heaters, to reduce slag formation, to facilitate the removal of slag deposits and suitable for improving fuel combustion efficiency.

It is generally known from combustion technology that slag particles deposits on various surfaces along the combustion path within a furnace form. Theoretically it has been deduced that the slag deposits mainly form because impurities are contained in the fuels. Are they however, once formed, these deposited slag parts catalyze known oxidation reactions, such as the oxidation of SO2 to SO3. Most furnace fuels contain a number of sulfur-bearing compounds because it is economical it is unacceptable to remove such compounds before putting the fuel in the furnace is initiated.

A well-known product of combustion is water vapor. It's general known that gaseous H2O and gaseous SO3 chemically form H2SO4 combine. When the concentration of gaseous H, SO4 in an incinerator increases, the dew point of the H2SO4 is reduced. The slag acts as an absorbent for the condensed H2SO4 thereby reducing the corrosion problems at lower temperatures still amplify. Furnace slag parts are impregnated with condensed H2SO4 and such impregnated deposits can cause significant metal destruction Cause boilers and other surfaces.

Sulfuric acid isn't the only acid found inside incinerators is formed. Other equally corrosive acids are formed and can destroy the furnace by bring about various corrosion mechanisms.

Another well known effect of slagging within Incinerators are the degradation of the heat exchange efficiency of the furnace. Reduced efficiencies arise because the slag acts like an insulator works: their presence on heat transfer surfaces sets the effective speed heat transfer through these surfaces.

In general, slag has a low fusion temperature and when it is in the molten state, it very often impinges on heat exchanger surfaces and adheres to them. After sticking, the molten slag is transported through the relatively cooler metal of the heat exchanger surface is cooled and solidified. Such adhering slag can then trap additional molten slag particles and possibly lead to the build-up of a tough deposit.

It is known that certain fuel or heating oil additives in the Intervene in the formation of slag on furnace surfaces.

Theoretically, it has been deduced that such an intervention is essentially is due to a metallic deposition mechanism. For example generate certain Fuel oil additives a special metal form of a chemical Species in the flame zone of an incinerator. One such chemical species that generally has a low activation energy, is then thermally decomposed, whereby the combustion surface with the deposited active form of a special Metal is equipped. The deposited metal is then more advantageous Show the process of slag formation on the combustion surface. Because of this metal deposition mechanism makes the resulting slag more fragile, them does not build up significantly on burn surfaces and it will likely carried away by convection currents inside the furnace.

A range of fuel and heating oil additives designed to to change the slag formation or, advantageously, in the slag formation to intervene are known from the art. However, these additions are necessary by their nature two-phase systems (dual phases).

Prior to this invention, it was both an aqueous phase and a continuous one Oil phase required for fuel oil additives to ensure good dispersion between the To obtain water-based fuel oil additives and a typical fuel oil.

However, dual-phase fuel additives do not disperse particularly good when added to liquid fuels and heating oils. The bad one Dispersibility of the fuel additives very often leads to numerous system problems, such as fouling on the surfaces of oil filters, sieve inserts and burners. Such a one poor dispersibility can mainly be due to the high viscosity of such Fuel additives are caused.

In addition to the poor dispersing properties, these are dual-phase Fuel additives also not inexpensive. The active ingredient is generally a water soluble salt. Since these salts are generally dispersed in oil, if they are sold, the dispersed product is necessarily more expensive, because of the presence of the required oil phase. The invention is much cheaper, because in the commercially available forms of the invention no so-called Oil phase is required.

The general concept of a so-called single phase saline solution comes up In and of itself, water-based is not new to the art. But were before Invention of such products technically unsuitable because they are not in fuel oils allowed to disperse and because they become unstable after relatively short periods of time became.

The aim of the invention is a completely water-soluble fuel oil additive, designed to reduce slagging and combustion efficiency to increase. Another object of the invention is to provide such a fuel oil additive provide which is extremely well dispersible in fuel oils.

It is also an object of the invention to provide such a heating oil additive which is relatively stable when dispersed in stored fuel oil is, and that such a dispersion stability within a technically practicable Storage temperature range is given, for example from about -290C to can range around + 490C.

According to the invention, an additive is proposed which, due to its Formulation intervenes in slag formation and increases combustion efficiency, which is nevertheless dispersible in fuel oils and has good dispersion stability shows.

A suitable formulation that has proven itself in practice is dispersible in oil The water-based fuel oil additive of the invention is: component Weight percent aqueous metal salt solution 94.0 Barquat MB-80 1.0 Tecsol A 1.0 Dowanol DB 4.0 Total Ingredients 100.0 Metal salt solution formulations used in the practical use of the invention have proven to be particularly successful are: Metal salt Salt in solution, wt .-% MgCl2 32 Cu (NO3) 2 53 Mg (NO3) 2 66.7 Mn (NO3) 2 50.0 Mn Cl2 40.0 Al Cl3 50.0 Al (NO3) 3 50.0 Mg 504 40.0 These aqueous solutions were not necessarily selected for their relative solution viscosity, but rather because of the relatively high metal content and the relatively low Costs. However, a low viscosity of the water-based additive is beneficial for one Good dispersibility of this water-based additive in the fuel oil is important. Many known water-based additives are metallic soaps of certain Fatty acids, and as such they are very viscous.

Some of them are so viscous that they can be used at typical storage temperatures for heating oils, which can prevail anywhere, can no longer be pumped.

According to the invention, the ingredient Barquat MB-80 "is a suitable one cationic surfactant.

A cationic surfactant is an essential ingredient the invention. The component called Barquat MB-80 ", which is available from Lonza, Inc., is manufactured chemically as an alkyldimethylbenzylammonium chloride to be classified, the hydrocarbon part of which is approximately 40% C12, approximately 50 Contains% C14 and approximately 10% C16 (each on a weight basis).

In addition to Barquat MB-80, the following are also cationic surfactants Means for emulsifying the water-based salt solution in the oil and therefore-in the suitable for practicing the invention.

Component, trade name Chemical classification Maquat MC 1412 (80% E) alkyldimethylbenzylammonium chloride Barquet 4280 alkyldimethylethylbenzylammonium chloride Bardac LF Dioctyldimethylammonium Chloride The first cationic surfactant mentioned above Agent is manufactured by Mason Chemical Company, the latter two of the above cationic surfactants mentioned are manufactured by Lonza, Inc. and offered in stores.

Of the cationic surfactants tested, have In particular, those whose hydrocarbon content is about 20% to about 60% C12, about 30 to about 70% C14, and about 5 to about 15% C16 (on a weight basis) place.

Many other cationic surfactants are used have been tested according to the invention, but they have not been found to be useful, if all objects of the invention are to be achieved. Of the cationic surfactants Agents that have been tested are commercially available: Barquat OJ-50, Barquat 4250, Barquat 4250-Z and Barquat 4280-Z. These surfactants Funds are also offered by Lonza, Inc.

According to the invention, the cationic surfactant functions as an emulsifier. It is the key ingredient in dispersing the soluble Metal salt solution in the fuel oil. The Tecsol A acts as a stabilizer component. Tecsol A is manufactured by Eastman Products, Incorporated, Rochester, New York and is mainly ethyl alcohol. "Tecsol" is a trade name for solvents from denatured anhydrous and denatured 95% ethyl alcohol. The part Dowanol DB acts as a coupler. Dowanol DB is owned by Dow Chemical Company, Midland, Michigan, and is primarily glycol monoether.

It is believed that the ingredient Tecsol A together with the Dowanol DB cooperates in solubilizing the cationic component and that an obtained microemulsion or micellar solution exists.

The currently best embodiment in practice of the invention consists in that (1) 32% M9Cl2, 53% Cu (NO3) 2, 66.7% Mg (NO3) 2, 50.0 t Mn (NO3) 2, 40.0% MnCl2, 50.0% AlCl3, 50.0 % Al (NO3) 3 or 40.0% MgSO4; (2) an alkyl dimethyl benzyl ammonium chloride the end (as far as the carbon chain lengths are concerned) about 20 to 60 wt% C12, about 30 to 70% by weight of C14 and about 5 to 15% by weight of C16 as the cationic surfactant Medium, (3) Dowanol DB as a coupler component and (4) Tecsol A as a stabilizer component used.

A viable manufacturing process for the oil dispersible fuel oil additive water-based of the invention consists in that one (1) a mixing vessel with the appropriate volume of a metal salt solution component, which usually fills (a) an alkaline earth metal from Group II-A of the Periodic Table, (b) a transition metal salt, or (c) a metal salt of a Lewis acid, (2) then the mixing kettle fills with the appropriate volume of the cationic surfactant ingredient, (3) then mix for 30 minutes, (4) then add the appropriate volume of the mixer to the mixer The coupler component fills, (5) then mixes for 15 min, (6) then the mixing kettle as well mix the appropriate volume of stabilizer ingredient, (7) then mix for 60 minutes and (8) then passing the resulting mixture through a serial filter. That filtered Mixture is then poured through a hollow shaft into streams of oil no. 6, residual oil or Used oil is injected before the oil is burned.

The metal salt solutions are water-based by the presence the appropriate cationic surfactant with the appropriate hydrocarbon chain lengths Made extremely well dispersible in oil. The unique oil dispersibility as a feature of the invention enables the injection and dispersion of the metal salt containing water droplets in the fuel oil before burning. Before the invention Only oil-soluble additives could be injected into oil and placed in the oil storage tanks be stored. It is now possible to use water-based solutions up to a relative small particle size (theoretically less than 10 µm in diameter) to disperse. Such a small particle size provides extensive stability in storage tanks (e.g. longer than 30 days).

It should be recognized that the invention with the feature of Fuel treatment additive containing a water-based metal salt solution, is not limited to the dispersion in heating oils. The additive according to the invention can also be sprayed on charcoal and on the furnace sections of heating boilers.

Claims (7)

Claims 1. Water-based fuel additive that is dispersible in oil, from (1) a metal salt solution, the metal salt being a representative of (a) a Alkaline earth metal salt of group II-A of the periodic table, (b) a transition metal salt or (c) a metal salt of a group consisting of a Lewis acid is selected, (2) a cationic surfactant, (3) a coupler component, and (4) a stabilizer component. >. Fuel additive according to claim 1, characterized in that, last the metal salt solution a water Basis and 32% (weight percentages in each case) MgCl>, 53% Cu (NO3) 2, 66.7% Mg (N03) 2, 50.0% Mn (NO3) 2, 40.0% MnCl2, 50.0% Contains AlCl3, 50.0% Al (NO3) 3 or 40.0% MgSO4. 3. Fuel additive according to claim 1 or claim 2, characterized in that that the cationic surfactant is an alkyldimethylbenzylanuaonium chloride mixture is, with approximately 20 to 60 wt. t of this mixture of alkyls with C-12 hydrocarbon chains, approximately 30-70% by weight of this mixture of alkyls with C-14 hydrocarbon chains and approximately r-15% by weight of this mixture of alkyls having C-16 hydrocarbon chains exhibit. 4. Process for the preparation of an oil-dispersible fuel additive water-based, characterized in that the following steps are carried out: (1) Filling a mixing vessel with a water-based metal salt solution, wherein as the metal salt a representative of (a) an alkaline earth metal salt of group II-A of the periodic table, (b) a transition metal salt or (c) a metal salt of a Lewis acid existing group is selected, (2) subsequent Loading this mixing vessel with a cationic surfactant; (3) then mix for 30 minutes; (4) then filling this mixing vessel with a coupler component; (5) then mix for 15 minutes; (6) subsequent Filling this mixing vessel with a stabilizer ingredient; (7) subsequent 60 minute mixing; and (8) then passing this mixture through a series filter. 5. The method according to claim 4, characterized in that as a further The step is to disperse this mixture in a fuel oil. 6. The method according to claim 4, characterized in that the further ~ step this mixture is intended to be sprayed onto charcoal. 7. The method according to claim 4, characterized in that as a further Step provided the spraying of this mixture onto the furnace section of boilers is.