WO1988003249A1 - Burner for the combustion of liquid fuel - Google Patents

Abstract

The fuel and air are brought together in a cylindrical mixing chamber (1), in which a depression can be created. The air is fed into the mixing chamber (1) via lateral openings in the housing (2) of said chamber, from an air chamber (6) surrounding the mixing chamber (1). A cyclone is produced in the latter and the fuel is admitted to said chamber (1) along its longitudinal center axis. The housing (2) of the mixing chamber (1) can be heated by at least one electric resistance heating element (3). The length of the mixing chamber (1) is greater than its diameter, and the lateral openings extend at least approximately over the whole length of the housing (2) and are slots (5) or bores (4) which open tangentially into the mixing chamber (1).

Description

 Burners for the combustion of liquid fuel

The invention relates to a burner for the combustion of liquid fuel, the fuel and air being brought together in a cylindrical mixing chamber in which a negative pressure can be produced by removing the air from an air chamber surrounding the mixing chamber via side openings in the housing of the Mixing chamber is guided into the mixing chamber and forms a cyclone therein and the fuel is admitted into the mixing chamber in the longitudinal central axis thereof.

Combustion of heating oil for heating is still the most environmentally friendly solution and is certain to dominate the next decade for the following reasons:

1. Coal is much more polluting than heating oil due to the high sulfur content and the poor controllability of the combustion. The emission of sulfur dioxide SO2 and soot and the dust emission are considerable.

2. There is not enough wood. According to a study by the Frauenhofer Institute for Wood Research in small furnaces, the burning of wood also brings with it enormous emissions problems with soot, tar, ash and various odor-intensive and harmful gaseous substances, the amount of which depends on the wood quality and moisture as well as on the way in which the wood firing is operated .

3. With electricity heating, it depends on how the electricity is generated. Caloric power plants only have an efficiency of approx. 50% and are fired with nuclear reactors, coal or oil. (The firing efficiency of an oil firing is between 90 and 95%). 4. Heat pumps and solar panels are for ours

Latitudes only make sense for the heating transition period. The payback period for such a system is at least 5 years.

The rising energy prices and the increasing environmental pollution of CO2 from the burning of carbon (heating - car - airplane) and the associated higher emissions of pollutants, such as sulfur dioxide S02, nitrogen oxide NOX and unburned carbon CO, on the one hand require even better combustion with oil firing and on the other hand, a reduction in fuel consumption through better insulation of the houses.

Whereas boilers with 30 kW were previously installed in single-family houses, today they are predominantly only boilers with 15 kW.

With optimal building insulation and modern installation of the hot water heating system, in future only boilers with 5 - 10 kW will be needed per family home.

Oversized heating systems often only have an annual system efficiency of 50% compared to modern installations with 80 - 90%.

Since oil burners with pressure atomizing nozzles only function properly on the market due to the small bore and narrow tangential slots of the atomizing nozzle only from 14 kW heating output, suitable oil burners with outputs of 5 - 10 kW are lacking for the following reasons. 1. The oil stoves used a lot in floor heating systems, which work according to the evaporation system, with an output of 5 - 15 kW, will be less and less suitable in the future due to the poor combustion results during the start and shutdown phase.

2. The "compressed air atomization" system, in which compressed air is used to atomize around 1 bar of heating oil, is reliable from 5 kW upwards. The combustion results are also very good. However, the manufacturing costs are disadvantageous because of the necessity

Compressor, etc. and the loud combustion noise.

3. Newly developed evaporation or gasification burners have so far failed due to operational safety and the excessive manufacturing costs.

The object of the invention is to develop a burner which, with an output of 5-15 kW, enables optimal combustion with the highest degree of firing and which is nevertheless inexpensive. The principle of oil gasification was chosen because of the optimal combustion that can be achieved with it.

From European patent application No. 79101956.5 a method for operating a burner for liquid fuels without a fuel pump is known and a burner device operating according to the method. However, this burner device works on the principle of a compressed air atomizer. The fuel oil is only atomized and not gasified.

European patent specification 28 025 describes a method and an apparatus for producing

Micro liquid droplets, also from a burner. Here, too, there is no gasification of the heating oil. The following criteria had to be solved for oil gasification:

1. Residue-free gasification of the heating oil so that there are no deposits.

2. Start and switch-off behavior: The gasification of the heating oil must be fully initiated in a fraction of a second when the burner starts - and it must also be possible to interrupt it immediately when the oil burner is switched off. If this is not the case, when the oil burner is started and switched off, oil vapor is lost due to a lack of ignitability.

3. Mixing with combustion air: the two light ones

Media Air and oil gas are difficult to mix due to the low kinetic energy.

The object of the invention was achieved by overcoming the problems mentioned in that the housing of the mixing chamber can be heated by at least one electrical resistance heating element and that the length of the mixing chamber is greater than its diameter and the lateral openings are at least approximately over the entire length of the housing extend.

The electric radiator or radiators inserted into the housing of the mixing chamber brings the housing to a temperature of 400 ° C. Only when this temperature is reached is the combustion air supplied first and then the oil supply. The oil, which enters the vacuum zone of the hot air cyclone directly from the feed tube, is roughly atomized by the rotating hot air movement and the vacuum and gasified in a split second by the hot air and radiant heat.

The gasified oil is mixed by an additional hot air supply to an air ratio n 1.1 to 1.15. A baffle plate is advantageously arranged on the outlet side of the mixing chamber. The ignitable gas-air mixture is ignited in front of the baffle plate by means of an ignition electrode and burns as a blue flame, absolutely soot-free and almost CO-free.

The radiant heat from the combustion chamber heats the combustion air to 80 to 90%, so that only 10 to 20% electricity (approx. 150 - 250 watts / h) is required for further gasification. The gasification temperature can be reduced to 300 ° C during operation.

The openings through which the air is introduced into the mixing chamber can be rows of holes or slots, or a combination of both.

It is advantageously provided that the openings open tangentially into the mixing chamber, whereby the best swirl effect is achieved.

The burner is advantageously arranged directly in the combustion chamber, so that the air is heated before it enters the mixing chamber. To ensure that warm air enters through all openings and not already cold air when

When the air chamber enters the mixing chamber, at least one deflection channel is provided.

Because of the hot, intense gas flame, higher NOX values can arise, as with normal pressure atomizing burners. It is therefore advantageously provided that a heat-dissipating block protruding into the flame is inserted into or formed on the housing of the mixing chamber, or that there is an auxiliary air opening next to the baffle plate. In the former case there is heat dissipation from the flame and in the second case understoichiometric combustion with an air ratio n of 0.7 to 1.0.

Various exemplary embodiments of the invention are described in detail below with reference to the figures in the accompanying drawings, without the invention being restricted thereto. Likewise, the reference numerals cited in the following patent claims are not intended to mean any restriction, they merely serve to make it easier to find related parts in the figures of the drawings.

1 to 4 each show a schematic longitudinal section through a burner according to the invention and FIG. 5 shows a section along the line A-A of FIGS. 1 to 4.

As can be seen from the figures of the drawings, the channel-shaped mixing chamber 1 is surrounded by a cylindrical housing 2, in which electrical resistance heating elements 3 are inserted.

In the exemplary embodiments shown, the lateral openings through which air is led into the mixing chamber 1 are formed by holes 4 and slots 5. The holes 4 and the slots 5 open tangentially into the mixing chamber 1. The air chamber 6 is formed by a housing 7. In the air chamber 6 there is a deflection channel 8, so that the air, as can be seen in the figures of the drawing, is first guided from the rear to the front end of the housing 2 and then returned again, whereby it passes through the bores 4 and the slots 5 into the Mixing chamber 1 arrives.

The counter heating elements 3 are able to heat the housing 2 to 400 °. As already mentioned, this is only necessary when the burner is started, after which the temperature can be lowered and the temperature from the combustion chamber can also be used.

The liquid fuel, for example light heating oil, enters the mixing chamber 1 via a feed pipe 9. The feed pipe 9 extends into the vacuum area formed by the tangentially entering air, so that the fuel is roughly atomized immediately. The temperature prevailing in the mixing chamber 1 immediately leads to gasification of the fuel.

A storage plate 10 is arranged on the outlet side of the mixing chamber 1. An ignition rod 11 is located in front of the storage plate 10. In the exemplary embodiment according to FIG. 2, a block 12 is arranged at the front end of the housing 2, which protrudes into the storage plate 10 and into the flame.

The block 12 causes heat to be dissipated from the flame to the housing 2. This means on the one hand an energy saving and on the other hand a reduction in the NOX values.

A reduction in the NOX values is also achieved in the exemplary embodiment according to FIG. 3, in which an annular secondary air opening 13 is provided in addition to the storage plate 10.

In the exemplary embodiment according to FIG. 4, a baffle plate 10 is also arranged on the outlet side of the mixing chamber 1.

The housing 2 has a flange 15 on the flame side, which forms the end of the air chamber 6.

On the one hand, preheated air in the mixing chamber 1 can pass the baffle plate 10 at the gap 16 and, on the other hand, secondary air reaches the flame through the bores 17 directly from the air chamber 6.

A temperature sensor 14 can also be inserted into the housing 2.

Claims

Patent claims: 1. Burner for the combustion of liquid fuel, the fuel and air being brought together in a cylindrical mixing chamber in which a negative pressure can be produced by removing the air from one of the Mixing chamber surrounding air chamber is guided into the mixing chamber via lateral openings in the housing of the mixing chamber and. forms a cyclone therein and the fuel is let into the mixing chamber in the central longitudinal axis thereof, characterized in that the housing (2) of the mixing chamber (1) can be heated by at least one electrical resistance heating element (3) and that the length of the mixing chamber (1 ) is larger than their diameter and the lateral openings extend at least approximately over the entire length of the housing (2). 2. Burner according to claim 1, characterized in that the lateral openings are slots (5). 3. Burner according to claim 1, characterized in that the lateral openings are rows of bores (4). 4. Burner according to claim 2 and / or 3, characterized in that the openings open tangentially into the mixing chamber (1). 5. Burner according to claim 1, characterized in that in the housing (2) of the mixing chamber (1) a projecting into the flame, heat-dissipating block (12) is used or is formed on this. 6. Burner according to .Anspruch 1, characterized in that in the air chamber (6) at least one deflection channel (8) is provided. 7. Burner according to claim 1, characterized in that a baffle plate (10) is arranged on the outlet side of the mixing chamber (1). 8. Burner according to claims 5 and 7, characterized in that the block (12) protrudes into the storage plate (10). 9. Burner according to claim 7, characterized by a secondary air opening (13) next to the baffle plate (10). 10. Burner according to claim 1, characterized in that the fuel is introduced via a feed pipe (9) into the mixing chamber (1), which extends into the vacuum zone of the mixing chamber (1).