EP0654600A1 - Method for treating liquid fuels before combustion - Google Patents

Abstract

To improve the combustion of liquid fuels, these are exposed to an electromagnetic alternating field which is generated by an electrical current having a fundamental oscillation of a frequency between 60 Hz and 150 Hz with at least one linear curve section in each half wave, and having integer harmonics of the fundamental oscillation, preferably by a rectangular wave.

Description

The invention relates to a method for treating liquid fuel before combustion by exposure to an alternating electromagnetic field.

It is already known to arrange a permanent magnet in a diesel engine of a truck adjacent to the supply line, the effect of which is to reduce the consumption of diesel oil. However, this is relatively low, because in the best case it is not more than 5%. In addition, it depends in particular on the orientation of the permanent magnet with respect to the magnetic field of the earth.

It is also known to apply an alternating electromagnetic field to the liquid fuel for an internal combustion engine (EP-A-0 389 888), for which it is also known to use an alternating field with a frequency between 16.5 Hz and 20 Hz (DE-A-1 037 765). However, this loading only leads to an extremely slight reduction in consumption.

It is an object of the invention to provide a way of treating liquid fuel and fuel, preferably diesel oil, before combustion, by means of which the consumption of fuel or Fuel is reduced while achieving the same performance from the combustion.

To achieve this object, a method of the type mentioned at the outset is designed in accordance with the invention in such a way that the electromagnetic field is generated by an electric current with a fundamental vibration of a frequency between 60 Hz and 150 Hz, which has at least one, preferably at least two, straight-line curve sections in each half-wave, and Integer harmonics of the fundamental oscillation are generated, the current preferably having a horizontal curve section in each half-wave, in particular in the form of a rectangular curve.

The combination of the selected frequency of the fundamental oscillation and the numerous, high-frequency harmonics or harmonics generated by the straight-line curve sections, in particular in the case of a square wave, results in a surprisingly pronounced reduction in the fuel or fuel consumption.

Particularly when the frequency of the fundamental oscillation is between 80 Hz and 120 Hz, preferably between 90 Hz and 110 Hz, there is a surprisingly high reduction in fuel or fuel consumption, which is above 10 compared to operation without exposure to an electromagnetic field % lies and which is optimally about 22%.

Of course, it is necessary to ensure a sufficient power density of the electromagnetic field, which can easily be achieved by tests for the individual application. It has been shown that for standard motor vehicle engines using a coil surrounding a fuel supply line with approximately 30 windings, a current supplied in the order of 4 mA to 6 mA and an amplitude of approximately 2 V _{SS is} sufficient, while an increase in the current above 10 mA and / or the amplitude above 10 V _SS no longer caused any significant additional effect.

Since the composition of the respective fuel or fuel, such as diesel oil, heating oil, gasoline, kerosene, alcohol (e.g. methanol), vegetable oils, the basic frequency that is optimal for the particular fuel or fuel also fluctuates. It is therefore expedient to have the basic frequency run through a frequency range periodically, for example with a period of 1 to 10 seconds, preferably 2 to 8 seconds and in particular 4 seconds to 8 seconds, this range being able to correspond, for example, to the frequency ranges mentioned above. In any case, this frequency range for currently commercially available diesel and heating oil and gasoline should contain the frequency 100 Hz, since this is obviously the optimal frequency or the optimal frequency is in the range close to 100 Hz.

It should be mentioned that feeding the coil with a sinusoidal current of the fundamental frequency alone, ie without harmonics, does not lead to an effect in the direction of reducing the consumption of fuel or fuel.

If the method according to the invention is used for the treatment of diesel oil or heating oil, the multi-turn coil can be arranged surrounding the feed line to the injection nozzle of a diesel engine or an oil heating system. In the event that the method is applied to a gasoline-burning four-stroke engine, the multi-turn coil can be arranged surrounding the feed line to the carburetor or to the injection system of the four-stroke internal combustion engine. The coil does not necessarily have to be placed near the injector; it can also surround the supply line at another location, for example in the part of the line leading from the tank to the fuel pump.

The invention is explained in more detail below with reference to the examples.

Example 1 :

A standard BMW 520 T-Diesel was used for an experiment. The vehicle was operated on a performance roller dynamometer against normal driving resistance at 100 km / h after having been brought up to operating temperature by a long journey.

The supply and return lines for the diesel fuel were separated between the engine and the tank, and both lines were inserted into a cylindrical measuring cup with an engraved scale division, which contained commercially available diesel oil (BP). The graduations on the measuring scale were 4 mm apart, which corresponded to a measuring cup volume of 50 ml.

The vehicle was initially started without modification of the engine and ran at medium speed until the suction and return lines were free of bubbles. The vehicle was then accelerated to 100 km / h and the measurement was started when this speed was reached. After an operating time of 3 minutes, the scale division of the measuring cup showed a fuel consumption of 5 graduation marks, i.e. 0.25 liters.

After this test, the vehicle was equipped with coils which had approximately 30 turns, a coil being placed around each of the feed lines to the injection nozzle of each cylinder. The coils were connected to a supply circuit which fed the coils with a current of 4.5 mA, the current being in the form of a square wave with an amplitude of 2 V _SS , which with a period of 6 sec had a frequency range from 0 Hz to Passed through 400 Hz.

The test described above on the power roller dynamometer was then repeated in the same way, but with coils loaded with electrical power. After 3 minutes showed there is a fuel consumption on the scale division of the measuring cup of 4 graduation marks, i.e. 0.20 liters.

Example 2 :

The vehicle from Example 1 was driven on the one hand without coils generating electromagnetic fields and on the other hand with the coils applied in the manner described in Example 1 over a distance of 500 km, the same route being driven in both operating cases and the driving speed, within the scope of the possible, was kept the same.

When the coil was not activated, the fuel consumption was approximately 11 liters per 100 km, while the load on the coils was approximately 8.7 liters per 100 km.

Example 3 :

The experiment from example 1 was repeated, but the coil was subjected to a square wave of constant frequency of 100 Hz. The reduction in fuel consumption was the same as in Example 1.

Example 4 :

The experiment from Example 1 was repeated, but the coil was fed with a square wave with a current of 4.5 mA and an amplitude of 2 V _SS , which ran through the frequency range from 0 Hz to 833 Hz with a period of 6 sec. The reduction in fuel consumption was only around 9%.

The significantly reduced reduction in fuel consumption compared to Examples 1 and 3 apparently is due to the fact that the actually effective frequencies around 100 Hz during the overflow of the relatively large frequency range only could act briefly on the fuel, so that the full effectiveness is not achieved.

Example 5 :

The experiment from Example 1 was repeated, the coil being subjected to a square wave with a frequency of 180 Hz. There was no reduction in fuel consumption.

Example 6 :

The experiment from Example 1 was repeated, but the coil was subjected to a square wave with a frequency of 440 Hz. In this case, too, there was no reduction in fuel consumption.

Example 7 :

The experiment was repeated as in Example 2 with a passenger car (Chrysler Voyager 3.0 LE) with a four-stroke engine with an injection system, the coil being placed around the supply line to the injection system. The coil was supplied with a current of 5 mA, which was in the form of a square wave with an amplitude of 3 V _SS and a frequency of 100 Hz. The gasoline consumption (Shell regular gasoline unleaded) was measured with an electric flow meter. The vehicle was driven on the highway with no wind and about 5 ° C outside temperature with the set speed (cruise control) without and with the coil under power.

When the vehicle was operated at a speed of 100 km / h, there was a 5% reduction in gasoline consumption when operating with the coil under power compared to operation without a coil, and a reduction in gasoline consumption when operating at a speed of 120 km / h 8th %.

The investigations carried out show that the exposure to liquid fuel or propellant commercially available in Germany in 1993, in particular heating and diesel oil and petrol, with an electromagnetic field which is generated by a current in the form of a wave exhibiting harmonics as a result of rectilinear curve sections , a reduction in consumption can be achieved when the frequency of the fundamental wave of the wave is close to 100 Hz or exactly at 100 Hz, but practically no reduction in consumption is achieved when the frequency of the fundamental wave is less than 50 Hz or 180 Hz or more is. In addition, it is shown that there is a size of the electrical power supplied to the coil for the reduction in consumption, above which there is no further reduction in consumption. However, should the fuel composition change, for example in terms of viscosity, density, etc., the optimal effect could also be achieved with a different frequency, which, depending on the composition of the fuel, is less than or greater than 100 Hz, or even greater than 150 Hz could be. Knowing the present invention, the person skilled in the art has no difficulty in determining the optimum frequency.

Claims (8)

Process for the treatment of liquid fuel before combustion by exposure to an electromagnetic field, characterized in that the electromagnetic field is generated by an electric current with a fundamental vibration of a frequency between 60 Hz and 150 Hz, which in each half-wave at least one, preferably has at least two rectilinear curve sections, and integer harmonics of the fundamental wave is generated. A method according to claim 1, characterized in that the frequency is between 80 Hz and 120 Hz, preferably between 90 Hz and 110 Hz. Method according to claim 1 or 2, characterized in that the fundamental oscillation has a horizontal curve section in each half-wave. Method according to one of claims 1 to 3, characterized in that the current has the shape of a square wave. Method according to one of claims 1 to 4, characterized in that the fundamental oscillation periodically runs through a frequency range. A method according to claim 5, characterized in that the period is 1 to 10 sec, preferably 2 to 8 sec and in particular 4 sec to 8 sec. Method according to one of claims 1 to 6, characterized in that a coil having a plurality of turns and to be supplied with the current is arranged surrounding the feed line to the injection nozzle of a diesel engine or an oil heating system. Method according to one of claims 1 to 6, characterized in that a coil having a plurality of turns and to which current is applied is arranged to surround the feed line to the carburetor or to the injection system of a four-stroke internal combustion engine.