WO2008009339A1 - Method and device for converting chemical fuels into mechanical energy - Google Patents

Abstract

The present invention relates to a method for converting chemical fuels into mechanical energy with the aid of internal combustion engines, wherein the pressure achieved by means of mechanical compression, and possibly by means of chemical reaction of the fuels together with the oxygen-containing working medium, and the temperature of the working medium by means of technical work performing expansion up to the ambient pressure, are utilized, wherein the temperature of the working medium after the mechanical compression thereof by means of isobar recuperative transfer of heat, preferably process-internal waste heat, and subsequently, the temperature and the pressure, before the expansion of the working medium, are increased by means of an approximately isochore chemical reaction of the working medium comprising supplied fuel.

Description

 Method and device for converting chemical fuels into mechanical energy

The invention relates to a process for the conversion of chemical fuels of all kinds, which are completely or incompletely burned with oxygen-containing gas mixtures, in particular of liquid and gaseous fuels, such as gasoline, diesel or heating oil, natural gas, as well as gases and liquids from the chemical conversion and the fermentation, but also of dust-like solid fuels, into mechanical energy by means of internal combustion engines.

The field of application is the construction of internal combustion engines for all sectors of the economy in which chemical fuels are converted for the purpose of technical work into mechanical energy, in particular for the drive of working machines, of means of transport as well as machines for the production of electric energy, as well as their application in the local, municipal, commercial and industrial use, as well as in transportation itself.

Although the state of the art in the conversion of chemical fuels into technical work with the help of internal combustion engines is very diverse in detail, but can be attributed to two basic principles, namely the internal combustion engines, as cyclically operating thermal cycles with compression, combustion and Expansion chambers are equipped, which are formed by pistons and cylinders on the model of gasoline and diesel engines, including the proposals for combining both engine concepts, as well as on the turbomachinery, the best known of which are the gas turbines. The most important work equipment of internal combustion engines for the conversion of chemical fuels into mechanical energy is air, which after compression and direct or indirect supply of energy in the course of expansion can convert latent energy and / or kinetic energy into technical work. The decisive thermodynamic difference between internal combustion engine and gas turbine lies in the type of transmission of chemical or thermal energy to the working fluid. In the internal combustion engine, this is done by chemical reaction of the working fluid air with the fuel under pressure under approximately isochoric conditions, which in addition to the temperature increases the pressure of the working fluid in the cylinder, while in the turbomachine after the mechanical compression of the air, the transmission of thermal energy through chemical reaction of the working fluid air with the fuel, but under approximately isobaric conditions, can be done so that not the pressure but the flow rate and thus the kinetic energy of the working fluid increases.

In the case of internal combustion engines, the increase in pressure due to compression and combustion is thus available for the expansion which carries out the technical work, whereas in the turbomachinery only the pressure from the mechanical compression is available.

The turbomachine therefore has the disadvantage that a higher proportion of the technical work occurring during the expansion must be used for the internal compression of the working fluid. The internal combustion engine can thus convert a larger part of the supplied fuel heat into mechanical energy and deliver it to external consumers compared with turbomachines. An effective measure for improving the fuel utilization in turbomachines is the in-process isobaric recuperative preheating of the working fluid after its mechanical compression by the hot exhaust gas from the expansion. The thermodynamically decisive disadvantage of internal combustion engines is that the further pressure build-up in the engine itself, achieved under approximately isochoric conditions, can not be fully utilized to increase the yield of technical work since the same cylinder volume is available for compression and expansion. The work equipment present after expansion still has usable pressures and temperatures for technical work. These properties of the working fluid allow the combination of the internal combustion engine with turbochargers, which utilize the working capacity of the exhaust gases to increase the pressure of the working fluid before the internal compression in the internal combustion engine.

The supercharging of the working fluid prior to the engine internal compression does not eliminate this fundamental deficiency of the reciprocating engine, it only allows the construction of smaller engines with higher power and improves the mass to power ratio of the engine. Indirect recycling of engine waste heat to the engine process is accomplished in this manner only when the higher pressure mass and thus reduction in engine size from the turbocharger in the pressurized working fluid is not cooled prior to its introduction into the engine. In particular, in large reciprocating engines but the charged working fluid is cooled, so that this method of indirect recycling of waste heat is not used.

In DE 197 34 984 it is proposed to compress the working fluid in the internal combustion engines only so far that the working fluid increased by the internal combustion process in the subsequent expansion stroke completely expands and thus can do more specific work. Furthermore, it has been proposed to combine an internal combustion engine with a turbomachine in such a way that the interaction of mechanical compression and approximately isochoric combustion in the pressure build-up before the Expansion is optimized and thus used to improve fuel efficiency.

The technical object of the invention is to make better use of the fuel heat supplied to the engine and to further reduce the specific fuel heat requirement of the internal combustion engines.

The technical problem with internal combustion engines is solved by the fact that the pressure of the working fluid built up by mechanical compression and approximately isochoric combustion is fully utilized for the conversion of fuel heat into technical work without intermediate cooling through expansion to near ambient pressure. According to the invention, the temperature of the working fluid, preferably air, after the mechanical compression, but before the supply of fuel, by isobaric recuperative supply of heat, preferably in-process waste heat, and subsequently the temperature and pressure are raised by approximately isochoric combustion.

It is thus according to the invention, the working fluid of the internal combustion engines, of whatever type not only not to cool after mechanical compression, but isobaric recuperative continue to heat before its temperature and pressure by chemical reaction with the fuel under approximately isochoric conditions are further increased ,

The prior art devices of internal combustion engines, that is, the internal combustion engines in which mechanical compression, combustion and mechanical expansion take place positively coupled in the same space formed by a cylinder and a piston, and the turbomachinery with integrated isobaric combustion between mechanical compression and expansion , are even in their execution as Rekuperationsgasturbine for the realization of the invention Method is not suitable because in internal combustion engines of the prior art, a recuperative preheating of the working fluid after the engine internal mechanical compression is not possible, and gas turbines do not over the pressure of the working medium increasing, almost isochoric combustion of the fuels do not allow.

The device according to the invention is therefore characterized by an expansion chamber, formed by a cylinder and a piston or a widening cell wheel chamber or by an expansion turbine, which is present after mechanical compression, isobaric recuperative heat supply and approximately isochoric combustion, compared to the mechanical compression larger and less receives higher pressure working fluid volume and expands with maximum delivery of technical work to a minimum pressure required to deliver the exhaust gas to the environment.

The economic advantage of the invention lies in the 20 to 50% lower fuel consumption in the conversion of fuel energy into technical work in the field of application.

EXEMPLARY EMBODIMENTS

Methods and apparatus are explained in more detail below by way of examples.

example 1

For the compression and expansion, a reciprocating engine was used, in which the compression and expansion were carried out according to the invention in different cylinders. Work equipment was dry air. A cylinder compressed the dry air, with 1 bar and 15 ⁰ C from the machine was sucked. After mechanical compression, the air had a pressure of 5 bar, a temperature of 200 ⁰ C and consequently a volume of 0.254 m ³ / kg. The volumetric compression ratio was thus 3: 1.

In this state, the air was forced out of the cylinder and fed countercurrently to a recuperator where it was preheated by exhaust gas from expansion to 680 ^° C., under approximately isobaric conditions, reducing the volume from 0.254 to 0.512 m ³ / kg. under real conditions, more than double, soared.

Thereafter, the working fluid was supplied to one or more combustion chambers formed by the piston and the cylinder when the piston was at top dead center, and in which the gas volume present after recuperation is completely exhausted for the purpose of almost isochoric chemical reaction with fuel supplied (isochoric combustion with formation of combustion gas) and subsequent expansion to ambient pressure.

By supplying fuel for an approximately isochoric combustion, to a temperature limited in the example to 1200 ⁰ C, the mass flow rate to the intake increased by approximately 1.4% and the pressure of the gas mixture of the compressed and preheated air and the combustion gases to about 7.6 bar in the combustion chamber. By subsequent, mechanical energy supplied expansion of the present after combustion gas mixture to approximately ambient pressure reached this a temperature of about 700 ⁰ C, sufficient for the recuperative preheating of the sucked and mechanically compressed air.

The expansion in the cylinder to ambient pressure is only possible if, according to the invention, the volumetric expansion ratio the volumetric Compression ratio is adjusted, ie the gas space in the cylinder at top dead center of the piston (combustion chamber) can absorb the volume increase from the isobaric heat transfer. This is achieved by adapting the cylinder bore of the combustion chamber to that of the compression cylinder, or the sum of the cylinder bores to the volume flow and to the piston stroke to secure the expansion to the ambient pressure.

The increase in the working fluid temperature from 680 to 1200 ⁰ C with adiabatic combustion requires the supply of about 610 kJ fuel heat / kg of working fluid. In contrast, the working fluid, when expanded to a pressure of 1.1 bar and an internal efficiency of the machine of 90%, can provide 585 kJ / kg of technical work, of which 200 kJ / kg must be expended for the compression of the working fluid.

This results in that the inventive recuperative coupling of in-process waste heat in the power process of a modified reciprocating engine according to the invention can halve the fuel demand for the same technical work.

Example 2

The method was implemented with a device consisting of a turbo-compressor, a recuperator and a piston machine, in which the compression of the working fluid with the turbo compressor and the approximately isochoric combustion of the fuel was carried out according to the invention recuperatively preheated air and the expansion in the cylinders of the piston engine. Example 3

The method has been realized with an apparatus which has been subjected to compression and expansion in turbomachinery, wherein the approximately isochoric combustion of the fuels with the recuperatively preheated air in cylinders of a reciprocating engine or in a cell of a cellular wheel constituting the combustion gas of the expansion stage of the turbomachine flow, ie between compression and expansion in turbomachinery.

Example 4

The method was implemented here with a device which according to the invention consisted of two cell wheels, one with a smaller and one larger comparable chamber volume, and a recuperator, wherein the chamber volume of the large cell wheel at the same position of the cells over that of the smaller cell wheel the ratio of Volume of the working fluid from after before the recuperative heat input was greater, ie Air as a working medium was mechanically compressed with the smaller cell wheel and then preheated recuperatively. After preheating, the working fluid of the chamber of the larger cellular wheel, which opens after top dead center, was supplied via a gas supply opening as long as it was approximately isobarically possible. Immediately after completion of the gas supply, the air was loaded in the now formed second chamber of the cellular wheel with fuel and carried out the approximately isochoric combustion under pressure and temperature increase. The cell wheel chambers of the large cell wheel, which then opened further, enabled expansion to near ambient pressure.

According to FIG. 1, a special variant of a device according to the invention is characterized by two cell wheels which are driven in the cell wheel housing 1 by a centric cell wheel core 2 and an eccentric ring traveler 3 which guides the discs 4 forming the chambers and which drives the expansion work to the outside, is formed so that the volumes of Chambers of the outer cell wheel 5 to the chambers of the inner cellular wheel 6 corresponds to the ratio of the volumes of the working fluid from to before the recuperative preheating. The chambers of the inner cell wheel 6 are used for suction and mechanical compression of the air and their supply for isobaric recuperative preheating, while the forming after top dead center chamber of the outer cell wheel 5, the isobaric recuperatively preheated working fluid, in the direction of rotation after closure of the Arbeitsmittelzuführung in the outer cell wheel as the combustion chamber 7 forms in which the fuel is introduced and the isochoric combustion takes place before the further increase in direction of rotation chambers 8 while releasing technical work on the eccentric rotor 3, the working fluid to ambient pressure and after passing through the give dead center via the recuperator 9 to the environment 10.

Claims

claims

1. A process for the conversion of chemical fuels into mechanical energy by means of internal combustion engines, in which the pressure achieved by mechanical compression and optionally chemical reaction of the fuels with the oxygen-containing working fluid and the temperature of the working fluid by engineering work expansion to ambient pressure, thereby characterized in that the temperature of the working fluid after its mechanical compression by isobaric recuperative transfer of heat, preferably in-process waste heat and subsequently, before the expansion of the working fluid, the temperature and the pressure by approximately isochorochemical reaction of the working fluid with fuel supplied, are raised ,

2. Apparatus for converting chemical fuels into mechanical energy, characterized by one or more expansion chambers, formed by cylinders and pistons, or widening Zellradkammern, or by expansion turbines, which receives the present after mechanical compression, recuperatively isobaric heat supply and isochoric combustion working fluid and with maximum release of mechanical energy to a pressure required to exhaust the exhaust gas to the environment.