FI124050B - Switchable multi-part engine and method of fuel switching of such a multi-part engine - Google Patents

Description

Interchangeable Multi-Engine and Method for Fuel-Switching Such Multi-Engine

The invention relates to a multi-fuel engine interchangeable from one fuel to another fuel, and to a method for switching fuel in a multi-fuel engine from a first fuel to a second fuel starting from the first fuel ratio.

Multi-engine engines are characterized in that they can optionally be run on different fuels. Document DE 40 33 843 C2 discloses, for example, a dual-fuel combustion engine with gas as the main fuel and self-ignition with liquid ignition fuel. To reduce exhaust emissions, a burner chamber is provided which is formed as a separate structural unit separated from the cylinder head.

DE 197 54 354 C1 discloses a known diesel gas engine in which an air-gas mixture 15 is ignited by means of an ignition jet. To reduce ΝΟχ emissions, a gas burner actuator is fitted with a regulator that can be pressurized according to combustion temperature and engine power. Depending on these quantities, the controller controls a setting member which affects the air permeability of the air blower.

20 Combustion of certain fuels, such as heavy fuel oil, may result in deposits in the combustion chamber which, when used with other fuels, such as gas, adversely affect additional ignition sources and thus interfere with the combustion process. Particularly after switching to another fuel, these deposits can act as sources of additional ignition, resulting in an increase in damaging and thus unwanted knockdown.

To counteract these phenomena, the combustion chamber must be burned to a high deposition prior to replacement. Free-burning within use

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In practice, hitherto it has been realized that the engine is temporarily run on a third fuel, which differs from the low formation of deposits. Another way to avoid knocking is to switch fuel in connection with the connection, the switching is performed with a reduced motor load, for example 75% of the rated power. Both are disadvantageous because switching to a third fuel is expensive not only in hardware but also in control technology or due to power reduction, the frequent switching during switching 35 becomes ineffective.

It is an object of the present invention to improve the switching from the first fuel to the second fuel in connection with the multi-fuel engine.

This problem is solved by the method of claim 1. Claim 9 places a control device for carrying out the method according to the invention, Claim 10 having a multi-component motor equipped with such a control device. The claims are directed to advantageous further developments.

The method of switching fuel of the invention from a first fuel to a second fuel in a multi-fuel engine comprises in particular the following process steps: 10 - From the first fuel ratio, the proportion of the second fuel is increased and the proportion of the first fuel is reduced to the intermediate fuel ratio.

- The engine is operated at this intermediate fuel ratio for a specified time interval.

- Subsequently, the proportion of the second fuel is increased further, and the proportion of the first fuel is further reduced to 15, until the second ratio of fuel is adjusted.

By running the engine in an intermediate fuel ratio, the deposits are burned out in a controlled time interval. The engine can then be operated on another fuel ratio. In mixed use, the intermediate fuel ratio reduces the rebuilding of the deposits, while simultaneously burning the combustion chamber free from the present deposits. In addition, knocking only appears to be diminished in mixed use. An advantage of the method according to the invention is that the engine can be operated during the fuel changeover without significant power reduction, preferably further at full load. The changeover is then made directly from the first to the second fuel ratio without the need to use a third fuel.

o The specified time interval can then be obtained from tables stored in a table format

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^ values which, in turn, may depend on other parameters such as ° fuel quality and instantaneous engine condition. Alternatively, the specified time interval 00 00 may be determined by knock sensors. Specified time interval in this case, preferably, when the knock sensors show a marked decrease in knock, especially knock no longer is detected.

The first fuel ratio is referred to as the available blend ratio of the first and second fuels, in which the proportion of the first fuel is predominant. In this case, especially up to 90%, up to 100% has been favored for the first fuel. In this context, the percentage of fuel proportions must always be understood as the proportion of the total energy brought into the combustion chamber by the fuel in question. The second fuel ratio, respectively, refers to the mixed ratio between the first and second fuel in which the proportion of the second fuel is dominant. In this case, especially 5 to 90%, up to 100%, is favored for another fuel.

Especially in the case of the second fuel ratio, it is common for the first fuel to comprise a certain proportion which is needed solely for the so-called ignition jet fuel requirement. The intermediate fuel ratio is called the fuel ratio, wherein the proportions of the first and second fuel are respectively between the first and second fuel ratio portions.

Preferably, at least the second fuel is ignited by means of an ignition jet, wherein at least occasionally during the fuel changeover, the amount of injection of the ignition jet is increased, preferably clearly, relative to the amount of injection of the ignition jet at the first or second fuel ratio. By increasing the amount of ignition jet injection, the mixture in the combustion chamber is burned faster, which acts against knocking combustion. Operation in the first fuel ratio thus refers to the operating mode in which the switching event has not yet begun. Operation in the second-20 fuel ratio thus refers to the operating state in which the changeover event has already been completed.

The above method is particularly suitable when the first fuel is petroleum, especially diesel, biodiesel or heavy fuel oil, wherein the term petroleum fuel also includes all other fuels whose combustion is capable of forming deposits and residues such as soot particles. The above method is also particularly suitable when the second fuel is a gas comprising all combustible gases such as natural gas, hydrogen,

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gaseous and similar gases but also other gaseous or injectable liquid fuels such as gasoline fuels or methanol.

00 30 Preferably, the fuel is increased at least occasionally during switching, the penetration depth of the ignition jet. This can occur, in particular, by increasing the injection pressure of the ignition jet. The effect of the penetration depth of the ignition jet results in a faster burn-out of the mixture, which in turn acts against knock-on combustion. The advantageous faster combustion of the blend is also accomplished by increasing the volume of the air / gas mixture contained in the ignition jet at least occasionally during fuel changeover.

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In a preferred embodiment of the invention, upon detection of a tactile combustion above the tolerance limit, i.e., when the tactile detector exceeds a predetermined threshold value, the amount of ignition jet injection is increased at least occasionally, the ignition jet penetration depth is increased, and / or re-adjusting the intermediate fuel ratio. These measures, which can be taken individually but also in arbitrary combinations with each other, can be used to control the knock-on burn. Knocking burning can then be detected by conventional knock sensors. These said operations 10 may be repeated many times, individually or in arbitrary combinations, until the burns have finally or sufficiently been burned free of flaking and can be returned to normal operation at another fuel ratio.

Preferably, the changes in fuel ratio to the second fuel ratio occur smoothly, particularly in a periodically linear fashion. With steady change, it is possible to aim for critical fuel ratios with increased knock-on combustion. If an increased knock is detected, at least one of the above actions can be immediately counteracted. Steady adjustment reduces the risk of sudden knocking, which is possible with sudden changes in fuel ratio 20. Notwithstanding this, however, it is made that, upon detection, a knocking combustion above the tolerance limit can be suddenly switched to a fuel ratio with a higher proportion of first fuel.

Preferably, the method for switching fuel in a multi-engine engine is controlled by a control device arranged to perform the method so that it can control the fuel ratio and analyze data, for example, knock detectors. In addition, the control device may be technically implemented to control the engine of a multi-engine or be designed as an independent control device

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^ for switching. The control device may be particularly integrated with the engine control device.

The invention will now be explained in more detail by way of an exemplary embodiment la. Other advantages and features of the present invention, as well as the sub-claims, are apparent therefrom.

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The heavy fuel oil / natural gas multi-component engine can be operated alternately with heavy fuel oil and natural gas. In the case of natural gas, the ignition also takes place with the aid of a small amount of 35 heavy fuel oil, which in the case of natural gas uses about 2% of the energy imported.

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Heavy fuel oil produces soot particles during combustion, which adhere to the combustion chamber. These soot particles are also still present in the combustion space after switching the fuel to natural gas and then acting as additional ignition sources for the natural gas, which contributes to the knock-on combustion of natural gas. In the following switching method described above, the soot particles from the heavy fuel oil to the natural gas are burned off so that fewer, preferably no at all, the soot particles are present in the combustion space when the natural gas conversion is complete.

To control the switching method, the heavy oil gas engine 10 has a control device integrated with the engine control device.

First, the amount of heavy fuel oil that serves as the fuel for the ignition jet is raised to about 50%, i.e., the amount of jet injection is increased. The proportion of natural gas is then steadily increased from about 0% to about 50%. At the same time, the proportion of heavy fuel oil is steadily reduced from about 15 100% to about 50%. Thus, an intermediate fuel ratio is controlled, with the proportions of heavy fuel oil and natural gas being about 50%. In addition, the penetration depth of the ignition jet and the volume of air / gas mixture contained in the jet are increased at least from time to time.

The engine is now operated at a defined time interval at this intermediate fuel ratio until combustion is completely burned free of soot particles. The interval is expressed by values stored in a tabular format, which are determined experimentally. The proportion of natural gas is then raised from about 50% to about 98%. At the same time, the proportion of heavy fuel oil is steadily reduced from about 50% to 2%. Here, too, the amount of heavy fuel oil that serves as the ignition medium for the jet 25 is again reduced to the starting value. The 2% share of heavy fuel oil, which is also fed into the combustion chamber for natural gas use, is due to 5 only the amount of heavy fuel oil needed to supply the jet.

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^ still in use in natural gas.

° The changes in the fuel ratio always have a smooth course, 00 00 being the time periods in which the changes in the fuel ratio take place linearly | a.

^ Throughout the changeover procedure, the motor is monitored by knock sensors. If knock sensors detect an increased knock, the proportion of first fuel will be increased at least occasionally depending on operating mode.

00 35 In addition, the amount of jet injection is increased at least from time to time depending on the application. Furthermore, depending on the operating condition, the penetration depth of the ignition jet 6 is increased at least occasionally or the volume of air-gas mixture comprised in the ignition jet is increased. Alternatively or additionally, if free combustion has already been carried out with 50% intermediate fuel ratio for both fuels and the proportion of natural gas is already more than 50%, the intermediate fuel ratio may be re-adjusted and the combustion chamber released at intermediate fuel ratio.

The driving energy released by the motor remains substantially unchanged throughout the switching event.

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Claims (4)

A method for switching fuel in a multi-substance engine from a first fuel to a second fuel starting from a first fuel ratio, the method comprising the following procedure steps: - raising the proportion of second fuel and reducing the proportion of first fuel up to an intermediate fuel ratio, 10. further increasing the proportion of second fuel and decreasing the proportion of first fuel to a second fuel ratio, characterized by decreased ignition of at least the second fuel by means of an ignition jet and that at least for a period of time during growth fuel is the amount of ignition jet injection amount in proportion to the amount of ignition jet injection in operation that occurs in the first or second fuel ratio, that the first fuel is an oil fuel, especially diesel or is heavy fuel oil, that the second fuel is gas, and that when detecting cracking combustion above a tolerance limit - the proportion of first fuel is increased at least occasionally, 20. the ignition jet injection rate is increased at least occasionally, - the ignition jet's penetration depth is increased, - the volume covered by the ignition beam; and - the intermediate fuel ratio is re-regulated. 25 Process according to claim 1, characterized in that the changes in the fuel ratio are uniform, especially periodically linear. δ ™ 3. Control device, characterized in that it is mounted to perform the method according to any of claims 1 or 2. 4. A multi-engine motor, characterized in that it comprises a control device 3. according to claim 3. LO O) O o C \ l