UA78971C2 - Metod for preparation of oxidizer for fuel burning - Google Patents

Abstract

A method for preparation of oxidizer for fuel burning consists in that prior to supply of flow of oxidizer to fuel burning zone one effects it with non-uniform electric fields with ambipolar anomalies. Those fields are formed by means of section electropolaroid-electric emitter, with sections alternating in polarity, this is placed in transverse direction with respect to flow of oxidizer. At that the sections are arranged as cells and/or rays for formation in cross section of flow of textures of point crown discharges and flowing electric charges emitted from those. The invention is directed to resource- and power preservation, protection andpreservation of environment against ecologically harmful discharges to atmosphere formed at fuel burning in air oxidizer.

Description

Description of the invention

The proposed invention relates to thermal power engineering and can be used in the combustion of various types of fuel (solid, gaseous, liquid, water pulverized coal, suspensions, slurries and their mixtures) at thermal power stations and in industrial and communal boiler units.

The invention is aimed at resource and energy saving, protection and protection of the environment from ecologically harmful emissions into the atmosphere, which are formed when fuel is burned in an air oxidizer.

The invention can also be applied in accompanying and related technologies for activation and intensification of 70 thermodynamic and plasma-chemical processes, for example, in the purification of working liquids and gases, as well as in the strengthening of electrophysical, electrolysis, pyrolysis, chemical and other reactions by means of the influence on them directly by an oxidant and/or physical fields used for its preparation. For example, electric and vacuum-acoustic with Raman-quantum amplification of the field, charge and medium by optically active fluctuations (The phenomenon of vacuum-acoustic activation... scientific discovery Mo124, application Mo140 dated 72 October 25, 1998.

A known method of ionization of air and gases by electric and thermal fields and a device that implements it, which includes an electrode in the form of a rod connected to a source of alternating current and a source of high-voltage pulse voltage (Russian Patent Mo2058510, E24E3/16, publ. 04.20.96br. Such a method and device for the preparation of the oxidizer allow to increase the electron emission and obtain a gas discharge at an electric voltage of several tens of kilowatts instead of hundreds and thousands. At the same time, the high voltage has a modulated form of successively repeated pulses of the same polarity and amplitude with a slow rise and a sharp fall.

The disadvantage of this method and the device implementing it is the high energy consumption, complexity and uncertainty of volume modulation of the discharge and, as a result, rather low efficiency of technological regulation when applied to large flows and volumes of oxidant preparation. p. 29 There is also a known method of preparing fuel for combustion with preliminary ionization of the oxidizer and a device that implements it, which includes electrodes in the form of rods connected to a source of electric voltage located in the walls of the outlet nozzle of the burner (authorized certificate of the USSR Mo1048245, P23013/44, published on October 15, 1983, and 1. The disadvantage of this method and device is the low stability of the gas discharge, the need for too high a voltage during the formation of ionization, which in the conditions of a dusty environment can lead to complications during -- 30 operation and control of the ionization mode of the oxidizer in real technology, which sharply narrows the area |- of use. The operational regulation of this method of preparation of the oxidizer is quite complex and not controlled, and in technologies with large flow rates of the oxidizer at volume velocities up to 10-20m/sec, it is practically ineffective. Therefore, technologies with this method of oxidizing ionization have a narrow field of application. 3o Known method of oxidizing preparation for burning fuel and the device that implements it, based on the application of a non-homogeneous stationary electric field and an electrode in the form of unipolar grids installed across the flow of the oxidizer and electrically isolated from the walls of the oxidizer pipeline (Patent

of Ukraine Mo24193 A, E23C11/00, publ. 07.07.98 1. "

The disadvantage of this method of preparation of the oxidizer and the device that implements it is the formation of only the contour Z 40 ionization of the oxidizer with short-range order of interaction, which does not give the opportunity to achieve a sufficient depth of ionization from the flow of the oxidizer, and also narrows the field of application in the technologies of TPP, CHP and other thermal energy projects, where large volumes and consumptions of oxidizer are used when burning fuel.

The closest in terms of technological and technical essence to the claimed invention is a device and technology containing a source of rectified high-voltage voltage and an oxidizing grid-electrode with drains of electric charges electrically isolated from the walls of the pipeline 49 (patent of Ukraine Mo52845, E23311/00, publ. and 15.01.2003.

Ge | However, this technology and the device that implements it do not ensure the proper metastability of the distribution of the ionized oxidizer in the air flow and require close installation of the grid - electrode with drains and electric charges to the inlet windows of the oxidizer of the boiler unit, which is not always possible due to the design of the -I 20 air duct. The distant location of the grid-electrode is associated with unjustified losses of leakage currents and emission currents for bulk ionization.

The invention is based on the task of creating such a method of preparing an oxidizer for fuel combustion that would be able to significantly intensify the fuel combustion process, sharply reduce the amount of supplied air (oxidizer) and the amount of outgoing gases by means of macrodialysis electrodestruction of the oxidizer by flowing electroreactive charges and direct electrosonic elastic in waves, with the help of

HF) of formed ambipolar anomalies of heterogeneous electric fields with the help of a sectional volume-cellular and/or volume-beam electropolaroid, and the latter is made linear in the form of sections alternating in polarity (- 0-00 - s Her tod), mainly from lattices- electrodes and grids-electrodes-screens, which have drains of electroreactive charges and elements of emission of direct 60 surface electric sound, while the sections of the polaroid are selectively (by polarity) placed in the cross-section of the oxidizer pipeline and oriented in it according to the directionality of the flow of charges and electric sound relative to the contours of the destroyed stochastic and thermogravitational fields, as well as to the formed superactive electrovacuumacoustic flow and anomalies of the transformed oxidizer prepared for supply to the fuel combustion zone. because the problem is solved by the fact that the method of preparing the oxidizer for fuel combustion, according to the invention, consists in the fact that, before the flow of the oxidizer is fed into the fuel combustion zone, it is affected by non-homogeneous electric fields with ambipolar anomalies, and these fields are formed with the help of a sectional electropolaroid - an electroemitter having sections that alternate in polarity and located in the transverse direction to the flow of the oxidizer, while the sections are made in the form of cells and/or rays, to create in the cross section of the flow textures of point corona discharges and trickling electric charges emitting from them

The following essential and predominant features are provided for the implementation of the specified method in the technology of combustion intensification: 70 - the oxidizer flow is subjected to electro-charge and electro-sonic macrodialysis with the help of ambipolar anomalies of non-homogeneous electric fields with the help of a sectional volumetric cell and/or volumetric beam electropolaroid, which forms flowing electroreactive charges and direct electrosonic elastic waves of selectively directed action and electrodestruction; - the electropolaroid is made linear in the form of sections alternating in polarity, located in /5 cross section of the oxidizer; - the sections of the electropolaroid are made of grid-electrodes and/or grid-electrodes-screens, which have drains of electroreactive charges and emissions of direct surface electric sound, which form energy pulses; - sections of the electropolaroid selectively by polarity (- z - z ii, etc.) are placed in the cross-section 2o of the oxidizer pipeline and are oriented in it according to the directionality of the outflow of charges and electric sound. in relation to the contours of the destructed stochastic and thermogravitational fields, as well as to the superactive electrovacuumacoustic flow of the converted oxidizer, which is prepared for supply to the fuel combustion zone, formed in the anomaly.

On the section of the electropolaroid in the form of grid-electrodes and grid-electrodes-screens and their cells with sinks of electroreactive charges and emission elements of direct surface elastic waves, through an operational electronic system, a rectified pulsed and intermittent electric voltage is supplied, for example, with a value of 20- 25 kV. A voltage with a modulated frequency of 20-40-80kHz is also applied selectively according to periodicity and intermittentness, which in the multicellular ambipolar and interelectrode gaps form anomalous contour, cellular, interelectrode and frame fields that intersect, in stochastic and "- by thermogravitational coupling and interaction with flowing electro-reactive charges and direct electro-sonic surface elastic waves, which ensure the creation of directed energy pulses. Charged grids together with drains in the form of electric needles, protrusions or concentrators create Ge! in the contour of the polaroid and air duct, anomalies of inhomogeneity and a pulsating inhomogeneous electric and electrovacuumacoustic field, through which the oxidizer (air) is passed from the discharge gas fan of the fan to the burners of the fuel unit. At the same time, as a result of the air-oxidizing agent passing through such an electric field, which is selective due to the anomalies of inhomogeneities, its ionization and activation occurs. Thus, the oxidizer entered the first phase of structured activity. After that, the activated charged oxygen particles flow from the emitter electric needles in the mode of reactive pulses of energy and are multiplied in vacuum-acoustic fluctuations of eddies and turbulences with the help of electro-sonic high-frequency « 70 waves of compression and discharge along the flow of the oxidizer. At the same time, depending on the resonant tuning of 7) c signals to nitrogen, the released free electrons and fluctuating vacuum-acoustic cavities provide the reactions of its transformation into oxygen. Along with this, from the electrophilic groups formed, (MO y) and triplet;" radicals (C MoO.) current-conducting channels are formed for the multiplication of super-reactive oxygen in the center of the duct into the fuel combustion zone.

At the same time, electroreactive energy pulses move charges into the plasma zone of fuel combustion. -I The degree of ionization of the oxidizer is determined by the magnitude of the leakage current and depends on the parameters of the emitter electric needles-collectors of electroreactive charges, due to the "electric wind" (with electrovacuum acoustic fluctuations of microturbulence behind the grids from the flow approaching with a large

Ge) at a speed of about 15-25m/sec. The length of the downpipes for this flow is selectively within 40-140mm and 5p depends on the configuration of the electrode grids and their number in the polaroid, which can be 2,3,4,5,6,7, etc.

Sh- The frequency of oscillations in microturbulence alternates with light radiation of 20-80kHz. shk The use of sawtooth, herringbone, convex-concave and needle-shaped electric sinks of charges and waves in the composition of grid-electrode cells and grid-electrode-screens is quite selective in terms of configuration and parameters and is determined by a wide variety of factors of charge and energy pulse formation, in plasma-chemical fluctuations and real powerful stochastic and thermogravitational factors and fields with a complex synergy of modes of formed electric and electrosonic fields, which each time require (F, experimental modeling of technological regulations similar to the real conditions of operation of each ka combustion intensification technology. Setting up the operating system and the formation of technological maps and electronic programs are integral procedures during implementation at each new heat energy 60 facility, TPP, CHP, and others.

Tests of a new combustion intensification technology based on the proposed method of preparing an oxidizer for fuel combustion showed that: - charges in energy fluctuating pulses have an overactive fuel ignition reactivity; - superactive oxidizer and atomic oxygen, as well as oxygen converted from nitrogen, contained in air and 65 They are used as an oxidizer during combustion, sharply intensify combustion reactions, promote more complete combustion of combustible fuel components, reduce the volume of oxidizer (air) required for burning the same amount of fuel compared to normal conditions, increase the combustion temperature and shorten the length of the torch, which leads to the intensification of radiant heat transfer. This has a positive effect on increasing the efficiency of heat units. A decrease in the amount of oxidant (air) leads to a decrease in heat loss with the outgoing gases. And due to the fact that the amount of air supplied for combustion decreases, the amount of flue gases discharged into the atmosphere also decreases, as a result, heat loss decreases. Therefore, with an unchanged content (percentage) of harmful substances in the outgoing gases, their gross emission into the atmosphere is sharply reduced and their harmfulness is practically eliminated; 70 - an ambipolar electric field with a triplet configuration (- z - z, etc.) ensures the formation of a superactive central part in the oxidizer flow and regulates metastability, i.e. long-term retention of charges and polarity fluctuations in the phase, which, in turn, contributes to the relief activation of the oxidizer in the process of its supply to the fuel combustion zone at lower voltages of electric and electrosonic fields, and also allows to form a selective relay multiplication of charges and energy with the help of an electrovacuumacoustic field, 7/5 oriented along the axis of the oxidizer pipeline, in its real stochastic, thermogravitational, and thermal fields prepared for supplying the oxidizer to the fuel combustion zone.

In addition, in industrial furnaces that require directed heat transfer from the torch to the heat-receiving surface, in the case of applying an electric field, the torch will "press tighter" to the heating surface.

Electrified fuel particles will approach the grounded heating surface and create a high-temperature zone near it, which gives some increase in the kinetic energy of the torch.

As a result, to produce a unit of heat, it is necessary to burn much less fuel than it would be necessary under normal conditions. All this leads to an increase in the efficiency of heat units and, as a result, to fuel savings. The effect will be higher if the emitter has a triplet polarity (- x -), and the "grid-electrode" cascade will be installed directly in front of the fuel heater and will form a selective stream of flowing electro-reactive charges and electric sound 20-40-80 kHz oriented towards the combustion zone and more

The essence of the invention is explained by a detailed description of an example of its implementation with references to drawings, i) where the combustion intensification technology is schematically presented in Fig. 1. Fig. 2 shows a variant of anomalies of polarities and inhomogeneities on one of the eight ducts (section AA in Fig. 1).

Fig. 1 shows the technological diagram of the placement of the equipment on the boiler unit. The implementation technology of the method of preparing the oxidizer for fuel combustion includes cabinets 1 for mounting and installation of high-voltage equipment (remotes and control units, high-voltage transformers and rectifiers, - modulators and converters), high-voltage cables 2, boxes of air ducts (oxidizer) 3, sectional Ge ! electropolaroids 4 with sections of grid-electrodes 8 with drains 9 of electroreactive charges and elements of electric sound emission, high-voltage pass-through and support insulators 5, boiler unit b with eight entrances to the oxidizer combustion zone and distribution equipment 7.

The method is carried out in the following way.

The air containing the oxidizer is supplied through eight air ducts Z to the boiler unit 6. In each duct of the air duct Z, the oxidizer is passed through the cells and gaps between the sections of the linear electropolaroid 4, installed across the pipeline, made in the form of sections of "electrode grids" that are electrically isolated from its walls 8 and grids-electrodes-screens, which have drains of electric and electroreactive charges located along their contour and elements of emission of electrosonic surface elastic waves combined on their surfaces. Each section of the electropolaroid 4 is separated from the metal duct box;" (oxidizer) With the help of high-voltage pass-through insulators 5 and connected through high-voltage cables 2 and distribution boxes 7 to the cabinets 1 and to the high-voltage equipment installed in them, i.e. to the remotes

Control, with control units, with high-voltage transformers and rectifiers and modulators -And pulses and breaks in modes of signal amplitudes and pulse trains.

Each high-voltage transformer increases the output (input) voltage from the power grid to the specified rectification value. Each high-voltage rectifier converts alternating current with a frequency of 50Hz (60Hz)

Ge) into direct current with an amplitude voltage in the described version up to 18-27KV. The electrical power supply of the 5p equipment is carried out in the mode with a voltage of 2208 and with an alternating current of 50Hz. Modulators form

Ш - electric sound with a frequency of 20 kHz, 40 kHz and 8 kHz and pulsations of a train duty cycle of 100 Hz and 200 Hz in a saw-like and selective form. The activation currents (leakage currents) exceed the indicators of analogues by 8-16 times and vary in intensity of burning (flame length) by a factor of 50-60. Microfrequency fluctuations vary between 20-100kHz with trains of electroreactive solitons of plasma-chemical energy pulses.

Each module is certified on the stand.

During the charging and discharging of grids-electrodes and sinks of electric and electroreactive charges and

F) elements of electric sound generation, an inhomogeneous electric field is created in the air duct with anomalies of sharp voltage in the circuit of the grid and between the positive and negative electrodes of the linear polaroid, which, together with stochastic and thermogravitational fields, orient the flow of ambipolar diffusion and destruction of the oxidant according to selectively chosen polarization processes, ionization, transformation, under the influence of which the oxidant passing through the cells and interelectrode spaces contacts and interacts with anomalies of field inhomogeneities, surface energy and fluctuations of electrovacuumacoustic origin (20-80kHz) and is sharply activated to the formation of atomic oxygen, and at a given modulation - and conversion of nitrogen into oxygen. Such an environment becomes a stronger oxidizing agent than molecular oxygen. At the same time, the power of the rectifiers is up to 20 W. 65 Fig. 2 shows a variant of polarities anomalies and inhomogeneities on one of the eight ducts, where the electropolaroid is made of electrode grids with sinks of electroreactive charges and elements of electro-sound emitters alternating in polarity relative to the grid-electrode-screen, which are connected in series in the triplet mode - polarities of phases (- z -) and emission 20-40-80kHz, in the mode of duty cycle synchronization and multiplication of solitons of fluctuations of electrovacuum acoustic activation in the direction of movement of the oxidant flow.

The triplet (- z -) of polaroid sections forms an axisymmetric ambipolarity, taking into account the leftward curvature of the movement of the central charge part of the flow and pulsating trains of solitons from the vacuum-acoustic fluctuations of the plasma-forming oxidizer. The frequency of energy pulses increases and amplifies asymmetrically, taking into account the influence of the stochastic field and thermogravitational factors at the transitions of flow rises and falls of the oxidizer in the turbulent circulation mode of the pseudo-boiling ignition front of the 7/0 fuel, which is introduced through the burners and special channels of the boiler unit. It should be noted that all eight air ducts can have different contours of a linear electropolaroid, both due to anomalies of ambipolarity and anomalies of inhomogeneities of electric charge and electro-emitter fields, including the number of sections of the polaroid.

These parameters are determined by the formed configuration of the fuel and oxidizer circulation in the pseudo-boiling and turbulating furnace combustion circuits and the repeated combination of the use of combustion products and /5 oxidation. This combination of microprocesses of energy pulses of combustion with undulatory (wave) radiation in the microresonance ranges of phase transitions, with the connection of vacuum condensate and its energy, is provided by electronic programming of the interaction of free electrons with their deficit in plasma and thermogravitational space (quantum illumination of combustion).

Control of the operational combustion system and synchronization of the supply of the active oxidizer is carried out by an electronic program, which is equipped with control and diagnostic subsystems of the mode with optimal intensity of combustion and heat removal. When changing the type of fuel, the renormalization and reregulation of the electropolaroid is carried out both in terms of charge, leakage current, and intensity according to the polarity of the electric sound. The electropolaroid has a cassette structure and is easily replaceable according to the configuration of ambipolar anomalies of inhomogeneities of electric fields with the contour configuration of cells and volumes of flowing electroreactive shocks Charges depending on the intensity of the contours of electric sound and its orientation in the stochastic and thermogravitational fields of the waveguide of the oxidizer pipeline. Design schemes for the configuration of cells, i) sinks and elements of emitters and their composition are strictly selective to the parameters of the state of the types of boiler units, the type of oxidizer and its thermodynamic ionization, taking into account the composition and impurities, as well as according to the parametric task and conditions for the formation of the electrovacuum-acoustic situation in the oxidizer and their plasma-chemical synchronization with the combustion process, combustion intensity, heat removal activity and ensuring the emission of complete oxidation products. -

The main task of preparing an oxidizer for fuel combustion in this method is to ensure the synchronization of ionization reactions and energy pulses of the release of volatile particles from the fuel with selectively prepared pulses of the electrovacuum acoustic activity of the oxidizer, i.e., with the newly prepared pulse electroplasmochemical and pulsating (fluctuating) state of the microvolume tanks with their surface charges and trains of solitons of a superactive oxidant that carry them, including atomic oxygen, formed by ambipolar anomalies of inhomogeneities from electric, electrovacuumacoustic, and electroplasmochemical components of physical effects of artificial origin. This process is called electromacrodialysis. In this regard, the main essence of electromacrodialysis of an air oxidizer is "

BECAUSE the flow of the oxidizer is divided in the cross section by a sectional volumetric cell and/or with a volumetric beam electropolaroid, ambipolar anomalies are formed on its surfaces and between the sections

And non-homogeneous electric fields, which create the conditions for the formation of charged electroreactive draining and charges and emission of direct surface electrosonic elastic waves of compression and rarefaction, and then, with the help of the hydrodynamic flow of the oxidant into the shadow surface of the cells of the drain sections of the electropolaroid

They form the conditions for the emergence and detachment of energetic vacuum-acoustic fluctuations and caverns of the pseudo-boiling -I property with active surface charges, which, together with periodically charged and discharged surfaces, ensure the emergence of electric and ion wind flows due to the interaction of molecules, ions and flow particles oxidizer with vacuum condensate and inhomogeneity anomalies

Ge) of ambipolar electric fields, in which the diffusion processes of charge interactions are concentrated in the central part of the oxidant flow. Through such interactions, the electrovacuum and acoustic microdestruction of oxidizing agent molecules, its phase transitions and transformation into a superactive plasma chemical state, in which

Kk oxidizer is multiplied in the fuel combustion zone, which, in turn, sharply activates the ignition of fuel particles and intensifies the output of volatile combustion, and, therefore, the conditions of selective (parametric) resonator and microdetonation combustion are provided, when fuel underburning is eliminated and harmful gas emissions are eliminated in atmosphere.

The claimed method, in the technological set of features, is able to solve the problem of more intensive and

Ф) active management of the fuel combustion process, due to the rather deep ionization of the central part of the oxidizer flow and the increase of its plasma chemical activity, which gives an increase in activation energy and an opportunity to reduce the consumption of fuel combustion volumes in TPP boiler units to 895; in boiler installations of industrial enterprises of industrial enterprises up to 5-895; to increase the efficiency factor of TPP thermal units to 3905, and accordingly

TZC up to 595; reduce the gross emission of harmful substances into the atmosphere to 7095.

Claims (1)

The formula of the invention b5, , The method of preparing an oxidizer for fuel combustion, in which before the flow of the oxidizer is fed into the fuel combustion zone, it is affected by non-uniform electric fields with ambipolar anomalies, and the specified fields are formed using a sectional electropolaroid electroemitter, which has sections that alternate in polarity, located in the transverse direction to the flow of the oxidizer, while the sections are made in the form of cells and/or rays, to create in the flow cross-section the textures of point corona discharges and trickling electric charges emitting from them. 6) "- in (o) (ee) and - - and? -i (ee) se) -i - ime) 60 b5