UA21391U - Mixed furnace oil - Google Patents

Abstract

A mixed furnace oil contains "POD" oil, to it chemical-recovery fuel oil is also introduced.

Description

Description of the invention

A useful model relates to compositions based on liquid hydrocarbons from the processing process, in particular, to 2 compositions using by-products of chemical production. Mixed furnace fuel can be used for combustion in boiler units, furnaces for heating and heat treatment, and, especially, in internal combustion engines (for example, in transport).

A known fuel mixture in the form of heavy residues of oil refining (fuel oil, tar, cracking residues), when their complex energy-technological use is expressed in the production of energy fuel used in boiler units of power plants (for example, when burning in nozzles) with satisfactory data on vanadium and sulfur corrosion, as well as on the levels of pollution of the air basin | The economic efficiency of improving the use of natural and fuel-energy resources and the implementation of environmental protection measures in the chemical industry" "POD" edited by B.V. Ermolenko and A.F. Maltseva.

Educational manual. - M.: Moscow State University named after D. I. Mendeleev, 1986. - pp. 50-521. 12 However, the cost of using such mixed fuels increases significantly as oil prices rise, and the use of such mixtures becomes insufficiently profitable.

Combustible oil residues of technological lubricant mixtures are known. Afterburning of the residues of these lubricants (in the form of unusable residues) on products or scrap can be carried out at acceptable levels of gaseous pollutants that are released, only in the case of the application of special measures to suppress these pollutants during combustion and subsequent gas purification in gas ducts that remove combustion products ("Zlement ! waste-free technology in metallurgy" L.A. Shultz. Teaching manual - M.: Metallurgy, 1991. - p. 167-169).

However, the use of such - unsuitable - combustible oil mixtures is possible during combustion only in chamber or layer modes, when it is not possible (except for obtaining some technological heating effect, for example, scrap heating) to achieve the goal of complex energy-technological use of combustible mixtures (for example, with the use of special heating devices type of nozzles). in

The closest in technical essence and effect achieved is the fuel composition with the inclusion of "POD" oil in the form of an additive in small doses of it to liquid fuel, due to which the effect of reducing hydrogen sulfide corrosion is achieved (TU B 00203826.009-95 and TU B 24.1- 05761672-146-2002 "POD oil (a mixture of low-boiling cyclohexane oxidation products) - go away! production of caprolactam!". --

"POD" oil is formed as a by-product of the production of adipic acid by hydrogenation of benzene Ge»! and subsequent oxidation of cyclohexane with air oxygen. "POD" oil is the trade name of a product consisting of a mixture of high-boiling cyclohexane oxidation products, mainly adipic acid esters and polycondensation products. Mainly "POD" oil is obtained as a waste product of caprolactam production at the "--" stage of catalytic oxidation of cyclohexane. 3o With the known variant of using a fuel composition based on liquid fuel with "POD" additives, the effect of reducing hydrogen sulfide corrosion is achieved. However, the disadvantage of mixed furnace fuel in terms of its closest analogues is that as the price of liquid fuel increases, the profitability of its use decreases significantly. If, on the other hand, a well-known composition based on "POD" oil is used (at favorable levels of "profitability"), its energy-technological use is significantly limited, since the burning of the well-known Z 50 composition (with a base in the form of "POD" oil) cannot be carried out using known, highly efficient on energy-technological use of heating devices (for example, nozzles) due to inadmissibility

Because of the high level of "POD" oil viscosity.

At the heart of this useful model is the task of improving and reducing the price of mixed furnace fuel by introducing into the base of the fuel - "POD" oil - water-reducing additives that reduce the viscosity of the fuel and allow it to be used when burning in efficient heating devices (for example, about nozzles). - This task is solved by the fact that in the mixed furnace fuel, which includes "POD" oil, boiler fuel and coke chemical fuel are introduced with such a ratio of components, in 9U09o by mass:

Ge) 20 "POD" oil 60-90 coke-chemical boiler fuel 10-40

The ratio of the declared components was obtained experimentally.

A well-known feature that coincides with the essential feature of the claimed useful model is the presence of "POD" furnace oil mixture in the fuel. c The difference between the proposed mixed furnace fuel and the composition, which is the closest of the analogues, is the introduction of boiler coke fuel into the "POD" oil at the indicated ratio of components.

The technical result of the use of the proposed mixed furnace fuel is the obtaining of a composition with the necessary viscosity and high heat of combustion, which is claimed to provide the possibility of effective energy-technological use at existing low costs (due to low prices for "POD" oil). Namely: use in boiler units - for generating steam or heating coolants, in heating furnace installations - for technological heating of materials, blanks and finished products, as well as as fuel - in internal combustion engines (for example, in transport) - for starting various kind of movers. 65 The use of the proposed mixed furnace fuel with the achieved viscosity enables uninterrupted and reliable supply of fuel through pipelines and other channels to known heating devices, for example, -D-

nozzle

At the same time, the supply of the oxidizer in the form of air or water vapor to the specified devices ensures reliable mixing with the oxidizer at the above-mentioned viscosity indicators of the declared fuel. Reliable mixing in the heating device (for example, a nozzle) of the fuel that is applied and the oxidizer that is supplied in excess, in turn, during combustion ensures complete combustion of the fuel that is applied, and this excludes the release of unacceptable pollutants during the combustion of the applied fuel .

The use of the proposed mixed furnace fuel with the achieved heat of combustion allows to reduce the specific consumption of heat and fuel during the effective performance of energy technological tasks. The efficiency of 7/0 is achieved due to the high profitability of using the proposed fuel due to the relatively low prices of the components included in the fuel.

In the manufacture of the proposed mixed furnace fuel, the specified components are loaded into the container at temperatures close to room temperature in the following order: first the "POD" oil, then the coke-chemical boiler fuel in accordance with the specified ratios, and the entire composition is mixed using mechanical 7/5 devices (for example , shovel).

The proposed compositions of fuel components can be easily reproduced.

Samples of mixed furnace fuel were obtained with the content of the components corresponding to the proposed ones, and initial ones beyond the stated limits, as well as the composition according to the closest analogues. The specified compositions are presented in Table 1.

10000006 2 1, 5 - compositions of components that go beyond the proposed limits; so b - the composition that corresponds to the closest analogs. -

The optimality of the percentage ratios of the components of the proposed mixed furnace fuel was determined during the fuel test when burning it on an experimental furnace stand in the conditions of the production site of the "Avtodorstroy" enterprise (Dnipropetrovsk).

The furnace stand is a lined working furnace chamber of a parallelepiped shape, in the front part of which a low-pressure nozzle of the Du 70 type is installed for burning fuel with an air pressure in front of the nozzle of 5.5 KPa and a fuel supply of 0.003-0.005 kg/s.

Air consumption was maintained at the level of 12-15 nm Z/kg, with excess air supply to exclude the release of Z from unacceptable gaseous pollutants from incomplete combustion.

From" The viscosity of the fuel before feeding it to the injector was controlled according to DSTU DST 33-2003 and maintained at a level of no more than Vmm/s.

The mass fraction of sulfur was controlled according to DST 19121. 15 To control the completeness of fuel combustion, regular sampling of combustion products was carried out from the chimney of the furnace stand, and they were analyzed with the help of a portable gas analyzer ORSA. - Analysis of the air in the combustion products removal zone was carried out in isolated cases (due to the time-consuming nature of the analysis) using a chromatograph.

Since there were difficulties in determining the heat of combustion of the fuel, this indicator was determined selectively according to DST s 0700 21261. that In the working area of the experimental furnace stand, in accordance with TU U 24.1-05761672-146-2002, the presence of gaseous pollutants in the air of the working area related to with the use of "POD" oil: adipic acid (according to MU 2877-83); carbon monoxide (according to MU 2905-83); methane, ethane, propane, butane, isobutane and other hydrocarbons (according to MU 3112-84); aromatic hydrocarbons (according to MU 3119-84); phenol and aniline (according to MU 59 3988-76); benzene and cyclohexane (according to MU - 4168-86); acetaldehyde (according to MU 4472-87); acetic acid (according to MU p. 4592-88); cobalt and its compounds (according to MU 5897-01).

The selection of optimal ratios of fuel components was carried out, focusing on achieving the maximum temperature of the lining of the chamber at the control point, chosen at a distance of 2/3 of the length of the chamber from the jaw of the nozzle to the beginning of the exhaust of combustion products. The maximum level of temperatures reached at control point 60 was (700-800)2eC.

This level is explained by significant heat losses during heating of the experimental furnace chamber, but, despite this, it can serve as a measure of reaching the maximum values of the heat of combustion indicators of the tested fuel mixtures. Measurements of the temperature of the lining were made regularly with the help of an XA thermocouple and a secondary recording device (potentiometer). 65 In Fig. graphic data of the experimental determination of optimal ratios of fuel components are presented. The curves of the graphs are built on the experimental points with the averaging of the experimental points by the method of least square deviations. The experimental points of the graphs were not detected due to their large number.

As a result, the highest values of the heat of combustion of the mixture were reached at the level of 40-4A5Mj/kg, which determined the optimal ratio of fuel components (in 9095 by mass).

The corresponding technical indicators of the tested versions of the ratio of fuel components, which are claimed, were determined as shown in Table 2.

And var. |at 202C, mms MJ/kg of total sulfur, 95 (relative combustion inefficiently efficient efficient efficient efficient

INN NINI SHI LI NI V NE Z knife is ineffective

The best comparative data on the characteristics of the mixed furnace fuel were obtained by the options of 2-4 ratios of components (in 9090 by mass) in the proposed technical solution: - fuel base - "POD" oil 60-90, an additive that provides the necessary fuel:fuel viscosity boiler coke chemical 10-40

For cases of optimal percentage ratios of fuel components, its supply was uninterrupted, and (57) combustion was efficient, the calorific value of combustion was 40-45 MJ/kg. Comparative fuel consumption was minimal.

The analysis showed complete fuel combustion in the presence of excess oxygen in the combustion products. Fuel combustion products consist almost entirely of CO 5, NO, Mo and excess O." The analysis in the zone of removal of combustion products showed the absence of unacceptable gas pollution.

The control showed the absence of unacceptable gas pollution in the air of the working zone of gas pollution. with

Thus, corresponding to the level of calorific value indicators no less than the indicators of traditional types of liquid hydrocarbon fuel, and the prices are much lower, the proposed fuel can be used (for example, when burning with the help of nozzles) for efficient and economically justified energy-technological use. Namely: for use in boiler units - for generating steam or heating coolants, in heating furnace installations - for technological heating of materials, blanks and finished products; in ts internal combustion engines - for powering various types of engines. h Additional technical effects from the use of the proposed mixed furnace fuel are: » - achieving the effect of combining the utilization (removal) of practically unusable waste (due to their incineration) with the simultaneous use of the received heat for energy-technological use; - reduction of costs for providing fuel for diesel internal combustion engines used in transport and for other technological needs, as the proposed fuel is competitive in comparison with diesel fuel of petroleum and bio-origin; - achievement of high inhibitory properties of the proposed fuel mixtures due to the introduction of "POD" oil into the fuel base, which has high anti-corrosion properties, while simultaneously obtaining 50 comparable heat of combustion indicators of the proposed mixtures with traditional types of fuel; - a decrease in the overall level of man-made pollution due to a decrease in the level of emitted harmful substances "6 (for example, sulfur compounds) when burning the proposed fuel in comparison with the burning of traditional types of liquid fuels.

Claims (1)

Formula of the invention Mixed furnace fuel containing "POD" oil, which is distinguished by the fact that coke-chemical boiler fuel is introduced into it with the following ratio of components, 9% by weight: 60 "POD" oil 60-90 coke-chemical boiler fuel 10-40. b5