DE1274781B - Method and device for improving the combustion efficiency of burners - Google Patents

Description

Method and device for improving combustion efficiency in burners The invention relates to a method for improving the flame characteristics using an electrostatic field on flames caused by burning of gases, vapors, liquids, solids and mixtures of such substances develop.

It has been known for over 100 years that flames are electrically conductive. It has been discovered in the past that this phenomenon is caused by certain types of ions. The most common view for the formation of ions in flames is based on the following approach: CH + 0 CHO + + e- CHO + + H, 20 CO + HäO + In the reaction zone of a flame made of pure hydrocarbons, concentrations of 1012 to 1014 ion pairs per cubic centimeter can be achieved.

Up to now, direct current electrostatic fields have been used to create flames to influence. The main disadvantage of using DC fields is in that the flame is destroyed and most of the energy is dissipated.

It is also known, the supplied fuel-air mixture before his To ionize the ignition point by an alternating current electric field, thereby to charge and, if necessary, to accelerate the ignition and atomization of the To improve the mixture.

In contrast, the invention is based on the object of the flame characteristics, such as the length of the flame, the luminosity of the flame, the color the flame, and the tendency to soot through the application of an electrostatic field with a low loss of energy to improve the flame.

Accordingly, the invention consists in applying the capacitors to an alternating voltage with a frequency between 1 and 2000 Hertz, preferably between 60 and 500 Hertz, in a burner whose flame is influenced by an electric field generated by oppositely arranged capacitors.

A burner is used to carry out the method according to the invention, in which a condenser designed as a hollow cylinder is concentric and a burner tube is arranged, which has a base at the end, the centrally a fuel supply pipe and eccentrically penetrating an oxidant supply pipe and concentrically at that within the fuel supply channel, isolated from the burner tube, one of the from Burner tube enclosed flame space axially penetrating the second condenser forming electrode is stored.

The burner flame can also be surrounded by two shells, one have metallic core, which in turn is enclosed on all sides by an insulating jacket is. The shells represent half of a hollow cylinder, with in the parting line there is a gap between the shells. The metallic ones are none applied as capacitors to an alternating voltage.

The subject of the invention is explained in more detail below with reference to the embodiments shown in the drawings. It shows F i g. 1 a section through a burner oremäß claim 2, F i g. 2 and 3 an electrode arrangement according to claim 3, seen from the side and from above, FIG. 4 shows a diagram of the brightness as a function of the field strength, FIG . 5 is a graph showing the effect of field strength on a propane diffusion flame, FIG . 6 is a graph showing the effect of an alternating current on a propane diffusion flame, FIG . 7 is a schematic representation of a device with two sets of electrodes, each of which has a different frequency. In Fig. 1 , 1 denotes a line through which the fuel is supplied from a source. The fuel line enters a bore 2 which is drilled into a plastic block 3, for example a tetrafluoroethylene. The block also has a bore in the vertical direction, and a glass burner tube 4 is inserted therein. The burner tube ends in a nozzle 5, which has a diameter of 2.2 mm. The burner tube is surrounded by a glass attachment 6 . The attachment has a diameter of 10.16 cm and is 50.8 cm long. The bottom of the attachment is formed by a rubber stopper 7 . The combustion air is supplied through line 8 which passes through the plug and ends at the bottom of a layer of lead shot 9. The purpose of this lead shot layer is to distribute the air over the cross-sectional area of the glass attachment and to bring about a steady flow of air vertically through the attachment. A nickel-chromium wire electrode 10 extends from an attachment point 11 in the tetrafluoroethylene block through the burner attachment to an attachment point 12 above the glass attachment. Both attachment points are insulated. A cylindrical copper electrode 13, which has a diameter of 12.7 cm and is 20.32 cm long, surrounds the glass attachment. In this way, the attachment isolates the nickel-chromium wire electrode 10 from the copper electrode 13, and this has the consequence that there is practically no current flow through the flame 20.

When the alternating current field is to be applied to the flame, the switch 14 is closed and the transformer 15 is thereby activated. The alternating current circuit is closed by connecting line 16 to the nickel-chromium wire electrode 10 and line 17 to the cylindrical copper electrode 13 . One of the different types with which a field strength of 1 to 500 kV can be achieved can be used as the transformer. A voltmeter 18 is connected across lines 16 and 17 , and line 17 contains an ammeter 19.

The device described above was used to change the flame characteristics of a propane flame. Propane was fed through line 1 to nozzle 5 at certain selected speeds between 0.05 and 15 1 / min. The inflow of fuel and air was regulated so that the flame had a length between 10.16 and 102 cm. Both laminar and turbulent flames were subjected to the action of an alternating current field. With a turbulent diffuse flame, which was created by burning 5 liters of propane per minute, it was found that the temperature of the nickel-chromium wire 10, measured by means of an optical pyrometer, under the action of a field of 500 V / cin of 9271 ° C. 9821 C had risen, with an energy dissipation of 0.03 watts occurring.

The alternating current field used according to the invention can be applied to gases such as natural gas, coal gas, propane, butane, generator gas and generally any other type of combustion gas that contains enough ionic particles that are influenced by an alternating current field. The process according to the invention can also be used with vaporous or liquid fuels which have an initial boiling point between 26.7 and 3711 ° C., preferably between 26.7 and 204 ° C. , such as naphtha, heating oil, light gasoline, kerosene, tar oil, petroleum residue, crude oil The liquid fuels are usually evaporated by heat or sprayed by being passed through a spray nozzle into a combustion zone in the form of vapors or fine droplets, mist or mist. The fuels can be mixed with air, oxygen, or other oxidizing gases before exiting the burner nozzle and comparable results are obtained when exposed to the field. Solid fuels such as coal and coke can also be used to create a flame.

In Fig. 2 shows an embodiment in which the flame 50 emerging from the burner 51 is arranged centrally in an electrostatic alternating current field. The electrodes 52 and 53 are curved and partially surround the flame and are about the same length as the flame. One electrode is connected to the transformer 55 by line 54. Line 56 connects the other electrode to the transformer. The electrodes are held in the desired position relative to the flame by means.

F i g. 3 shows that the electrode 52 is coated or covered with an electrically insulating material 57. The electrode 53 is also coated or covered with an insulating material 58. Suitable insulating materials are non-combustible materials such as ceramic substances, alundum, etc.

In the graphic representation of FIG. 4, the field strength is plotted on the abscissa and the luminosity is plotted on the ordinate. The values were obtained using an apparatus such as that shown in FIG. 1 has been determined. A photocell was set up pointing towards the flame. The voltage was varied between 0 and 10 kV. The luminosity of the flame is the amount of light given off by the flame . Expressed as flame quality, a yellow flame is a flame of low quality and a blue flame is one of very high quality. The in F i g. 4 graphs show that the luminosity of propane diffusion flames, which are obtained by burning 11 or 10 1 propane per minute, decreases as the intensity of the alternating current field is increased.

F i g. 5 gives another method by which the effect of the field strength on the flame can be illustrated. One as in Fig. The device shown in FIG. 1 was modified so that it could be used to supply nitrogen to the burner. If the ratio of propane and air is determined in such a way that a luminous (yellow) flame is produced, then one can reduce the luminosity of the flame by adding nitrogen to the fuel. This is possible because the addition of nitrogen to the propane increases the turbulence of the flame, which means that the fuel is more effectively consumed with the air.

The curve shows that if no electric field is applied, more than 1.7 liters of nitrogen per minute must be added to the propane in order to achieve a non-luminous flame. It is necessary for the less nitrogen, the higher rises the strength of the AC field. At a field strength of around 8 kV / cm, the nitrogen content required to achieve a non-luminous combustion is around 1 l / min. The alternating current field was also applied to a flame which was generated from a premixed gas of 0.5 liters of air per minute and 21 propane per minute with the secondary air supply being set to 2 l / min. As the field increased over a range of 0 to 10 kV at 60 Hertz, the amount of nitrogen required decreased. These results show that field-assisted combustion provides improved results for both diffusion flames and flames from premixed gases.

In Fig. 6 shows the effect of frequency variation on the amount of nitrogen required. As previously in connection with FIG. 5 , a lower amount of nitrogen required is indicative of improved combustion. The recording shows that AC frequencies above 60 Hertz produce improved combustion. Frequencies between 1 and 2000 Hertz are sufficient to generate fields that can be used according to the invention, frequencies of 60 to 500 Hertz being preferred.

In Fig. Figure 7 illustrates an embodiment of the invention in which two separate isolated AC electrostatic fields at different frequencies are passed through a flame. The transformer 101 supplies an alternating current of 60 Hertz of the desired voltage, with which a field is created between a group of electrodes connected in parallel, which is denoted by reference number 102, and another group of electrodes also connected in paraffle, which is denoted by reference number 103, can be adjusted. A second transformer 104 supplies a 120 Hertz alternating current of the desired voltage, and this allows a further field between one group of electrodes connected in parallel, denoted by reference number 105 , and another group of electrodes connected in parallel, denoted by reference number 106 is designated, build up. Both pairs of electrode groups are arranged on opposite sides of the flame, which emanates from the burner 107 in the vertical direction.

All electrodes are covered with insulation. The frequency of the two pairs of electrode groups can be in phase or out of phase. For example, if one set of electrodes has a frequency of 60 Hertz, the other set can operate at a frequency of 120 Hertz or also at 100, 160, 300 or more Hertz. Any desired number and arrangement of electrode sets in a horizontal or vertical plane can be provided, and one or more electrostatic fields can be provided, the lines of force of which intersect the flame at any desired angle.

Claims (2)

1. A method for improving combustion efficiency in a burner for gaseous, liquid or solid fuels, the flame of which is influenced by a signal generated by oppositely arranged capacitors electrostatic field, d a d u rch in that the capacitors to an alternating voltage having a frequency between 1 and 2000 Hertz, preferably between 60 and 500 Hertz, are applied. 2. Burner for carrying out the method according to claim 1, characterized in that a hollow cylinder designed as a condenser (13) is arranged concentrically around emi burner tube (6) , which has a bottom (7) at the end, the centrally a fuel supply pipe (4) and eccentrically penetrates an oxidizing agent supply pipe (8) and in which concentrically within the fuel supply passage, isolated from the burner tube (6), an axially penetrating from Bren nerrohr (6) enclosed flame room, the second capacitor forming electrode (10) is mounted. 3. Burner for performing the method according to claim 1, characterized in that the burner flame (50) of two a metallic core (52, 53) which is surrounded on all sides by an insulating jacket (57, 58) , having shells, the halves of one Represent hollow cylinder, is surrounded by leaving a gap in the parting line and the metallic None (52, 53) are applied as capacitors to an alternating voltage. Documents considered: German Auslegeschrift No. 1 121 762; U.S. Patent No. 2,766,582; Book by Ph. L en ar, "Deutsche Physik", Vol. 4, 1937, pp. 212 and 213, section 510; Journal »Archiv für Energiewirtschaft«, Volume 18 from January 10, 1964, Issue 1, pp. 16 and 17.