DE2318523A1 - COMBUSTION DEVICE - Google Patents

Description

Munich, April 12, 1973

Nissan 'Motor Company, Limited Yokohama City / Japan

Combustion device

The invention relates to a combustion device and, more particularly, to a combustion device in which the The release of toxic compounds is prevented or reduced to a minimum. The invention also relates to the use such combustion devices in heat engines.

Among the toxic chemical compounds that are in exhaust gases of combustion devices and internal combustion engines like them currently commonly used, included s ^ nd, belong unburned hydrocarbons, carbon monoxide and nitrogen oxides. These toxic compounds are a major cause of air pollution in cities and even suburbs. There are several ways to remove the toxic compounds from exhaust gases Devices have been developed and tried. That is true

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especially for internal combustion engines and burners for industry and household, ovens, boilers and other devices. To get rid of unburned hydrocarbons and carbon monoxide Devices have already been developed to remove exhaust gases, with which a complete combustion of the fuel or re-oxidation or afterburning of exhaust gases as they pass through the exhaust gas paths of the combustion device, of the internal combustion engine or the turbine flow, are to be achieved. With a complete combustion of the fuel or a renewed oxidation of the exhaust gases, however, nitrogen oxides arise, so that after a compromise between the Demand for the removal of carbon monoxide and unburned hydrocarbons and the removal of nitrogen oxides must be searched for from exhaust gases.

However, both requirements cannot be fully met at the same time, since in the conventional combustion devices the fuel is burned with air and air supplies not only oxygen but also nitrogen, so that nitrogen oxides can form.

The invention is based on the object, a heue combustion device and a heat engine, the one such combustion device contains to develop in which the fuel with an oxidizing gas that does not have any Contains nitrogen, is burned so that the exhaust gases are completely free of toxic nitrogen oxides. Because that's for incineration

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The oxidizing gas used in the fuel does not contain nitrogen, the fuel can have an improved effect or with high temperature are burned in such a way that the exhaust gases are not only free of nitrogen oxides but also free of carbon monoxide and unburned hydrocarbons produced by an incomplete Combustion of the fuel are present in the exhaust gases.

According to the invention, liquid hydrogen peroxide (H ₂ O-) is used as the oxidizing agent for the fuel. The hydrogen peroxide decomposes exothermically to water and oxygen in the presence of a catalyst, for example a material based on silver, as follows;

K ₂ O + 1/2

This exothermic decomposition of hydrogen peroxide is accompanied by the generation of heat, so that the temperature of the gas mixture formed rises to about 700 ° C. The gaseous mixture of water vapor and formed in this way Oxygen contains a large amount of nascent oxygen, so it is extremely chemically active. So if this Mixture with a fuel such as gasoline, heavy oil, Kerosene, or liquefied natural gas, comes into contact with the Fuel burned quickly according to the following equation!

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+ 1/2 O ₂ + C _n H _m ^ H ₂ O + CO ₂ ,

where C ίΐ generally for a hydrocarbon fuel η m

stands. The fuel gases formed in this reaction are
completely free of nitrogen oxides, and since the temperature of the fuel gases usually falls within a range of 2,000 to
2 300 C rises, which is more than sufficient for complete combustion of the fuel, the exhaust gases contain practically no unburned hydrocarbons or
Carbon monoxide.

The heat generated during this combustion is usually too great and the volume of the combustion gases is insufficient to generate the energy required for an internal combustion engine or to heat the water for a steam engine satisfactorily. This heat also ground the inner wall of a combustion chamber and parts that make up the
Fuel gases are directly exposed, so it overheated
serious damage to various parts associated with the internal combustion engine can occur. Therefore, the fuel gases must be diluted with a further fluid so that the temperature of the working medium is lowered to a suitable value and at the same time the total volume of the working medium is increased. In conventional incinerators or machines containing them, large amounts of

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gene used in air as an additional medium, so that the Use of powerful blowers becomes necessary. However, this makes the heat engine or the heat engine proportionate large, and relatively little energy is generated. According to a preferred embodiment of the invention Water is therefore used as a diluent for the fuel gases. This water is in a controlled amount the combustion gases produced by the combustion of the fuel in the presence of oxygen and those produced by the decomposition The water vapor generated by the hydrogen peroxide is injected and rapidly evaporated, increasing the temperature of the gas mixture decreased and the total volume of the working medium increased, Although water has a high cooling capacity because of its large latent heat of evaporation, it can be relatively less Quantity used / ends, so that the size and capacity of the feeder can be kept correspondingly small.

Because of the high temperature of the gases produced by the exothermic decomposition of hydrogen peroxide, combustion can occur svojrichtung the 7 * rt described above and an internal combustion engine in which such a machine is used, with any type of fuel, including liquid fuels, such as gasoline, kerosene and light or heavy oil, gaseous fuels such as liquefied natural gas or Hydrogen and solid fuels, such as those produced in particular from plastic, are operated. if

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relatively cheap fuels are used up, the cost of hydrogen peroxide is largely eliminated, so that the total cost of fuel for the operation of an internal combustion engine or an internal combustion engine with such an internal combustion engine with the operation conventional incinerators associated with mixtures of high quality hydrocarbon fuels and air are comparable or even lower.

The invention thus relates to a combustion device which is characterized; that they have a combustion chamber for burning a fuel, a device for introducing a fuel into the combustion chamber, a device for introducing hot oxidizing gases, the by exothermic decomposition of hydrogen peroxide generated in the combustion chamber to the fuel in the combustion chamber to burn and thus to generate Brennaase, as well as a device for introducing a further fluid into the Combustion gases in such a way that a working medium of suitable temperature and volume is generated on v / eist.

According to the invention, an internal combustion engine of the type described above is preferably used in a heat engine, like a steam engine or a steam and cooking, -HyV> rid ~ engine used to take advantage of the combustion device

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with the temperature and volume of the working medium can be controlled in a considerably wide range and complete combustion of the fuel can be achieved can be evaluated without the formation of toxic oxides of nitrogen.

The invention therefore also relates to the use of the combustion device described above in a heat engine. Such a heat engine has the combustion device described above in combination with a Veidanpfer, including an evaporation skaramer with a gas inlet, which is in communication with a combustion chamber of the combustion device, so that hot working medium passes into the evaporation chamber, »at least one leading through the evaporation chamber») Pipeline, a device for introducing water into the pipeline in order to generate steam therein by heat exchange between the water in the pipeline and the working medium in the evaporation chamber, and a steam expansion device continuing from the outlet of the pipeline, in which the steam expands and generates drive energy will be on. Steam relaxed in this way and under reduced pressure can be released into the air or, if desired, returned to the water supply device and the pipeline in the evaporator device via a condenser. The gases in the evaporation chamber can also be released into the air, or ι

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Since these gases consist essentially of water vapor and carbon dioxide, the carbon dioxide can be released into the atmosphere released, and the water, returned to the water supply system will.'

The evaporation device can be made of conventional heat-resistant material exist or be protected by such material as that introduced into this facility Working medium is cooled to a suitable temperature by injecting an additional fluid into the fuel gases. The additional fluid can be atmospheric air or water; however, the latter is for the reasons mentioned above preferred. However, if the evaporation device is formed from materials of high heat resistance or by a such material is protected, the fuel gases can be introduced directly, i.e. without the addition of an additional fluid, into the evaporation device, which is still important from the use the heat engine depends.

As a result of the decomposition of the hydrogen peroxide and the combustion of the fuel in the presence of water, as can be seen from the above reaction equations, abundant amounts of water are formed, as the working medium generated in a combustion device of the type described contains a large amount of water vapor

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Working medium directly than the fluid that produces energy on the Part of a machine. If this embodiment is preferred, the evaporation device can can be omitted, and the working medium produced by diluting the fuel gases can be sent directly to the expansion device are fed. Relaxed water vapor or steam can be vented directly into the air or via a condenser and, preferably, also via a separating device, from the carbon dioxide contained in the steam the atmosphere is released, fed back to the supply device for additional fluid of the combustion device will. A heat engine of the type described above is then of particular advantage when it comes to saving space matters because an evaporation facility, which is generally quite bulky, is not used will.

A combustion device according to the invention can be used in a gas turbine, such that in the Device generated hot combustion gases can be used directly to operate the impeller of a turbine without that a cooling or diluting fluid is added to them. Since in this case the fuel gases from the combustion device have a temperature of about 2,000 C, as mentioned above, it is generally necessary that the expansion and utilization of these gases gradually using a complete

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xen energy conversion mechanism takes place and that the components exposed to these gases are made of certain heat-resistant materials are made, including a relatively large and expensive turbine system is required. Around Avoid problems and heat in a combustion device Effective use of the gases generated in the manner described is, according to the invention, a steam and gas hybrid system provided in which the thermal energy is generated in a combustion chamber of a combustion device Gases partly to operate a gas turbine and partly to operate one. Steam turbine is used. Such hybrid system can be an internal combustion engine, including a gas expansion device that works with the Combustion chamber of the combustion device is in communication, so that hot gases are expanded from the combustion chamber and ' Supply energy to operate a gas turbine, and an external combustion or steam engine with one of the combustion chambers the combustion device associated evaporation unit for absorbing heat from the combustion chamber, a device for introducing water into the evaporation device to generate steam and a steam expansion device, which connects to an outlet of the evaporation unit, so that the steam relaxes and provides energy to operate a steam turbine can be generated.

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In the drawings is;

Fig. 1 is a schematic Veransehaulichung a Combustion device according to the invention;

2 shows a longitudinal section through a preferred embodiment of a combustion device, which is part of a combustion device as illustrated by FIG is, forms;

3 shows a section corresponding to FIG. 2 through a modification of a combustion device, as illustrated by Figure 2;

4 shows a section corresponding to FIG. 2 through a further modification of a combustion device, as illustrated by Figure 2;

FIG. 5 is a schematic illustration of a steam engine having one as illustrated in FIG. 1 Having combustion device;

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FIG. 6 shows an illustration corresponding to FIG. 5 a modification of a steam engine as illustrated by FIG. 5.

FIG. 7 shows a representation of a further modification of a steam engine as illustrated by FIG. 5 is;

Fig. 6 is a schematic illustration of a

Steam and gas hybrid system with a modified one Arrangement of a combustion device as illustrated by Fig. 1;

9 is a longitudinal section through an essential component of a preferred embodiment of a Hybrid steam and gas system of the type shown in Figure 8; and

Fig. 1o is a longitudinal section through this embodiment the line X-X of Fig. 9.

The combustion apparatus according to the invention illustrated by FIG. 1 comprises a combustion device 12 with a combustion cylinder 14. The combustion cylinder 14 has a combustion chamber 16 and a fuel supply device 10. The fuel supply

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device 8 can be constructed and arranged in any way, depending on what kind of fuel is used will. The fuel can be introduced continuously * or periodically into the combustion kettle 16 and is in The presence of hot oxidizing gases emitted by the oxidizing agent supply device, as described in more detail below, burned.

The oxygenation agent supply device has a container 2o in which hydrogen peroxide (H ₂ O ₂ ) is in the liquid state. The bottom of the hydrogen peroxide container 2o has an outlet which leads into a line 22, which leads via a catalyst device 32, as described in more detail below, and an injection nozzle 24 into the combustion skaiamer 16.-To the liquid hydrogen peroxide to flow out of the container 2o, suitable pressure means are provided. The pressure medium shown here consists of a container 26 in which there is a compressed inert gas such as nitrogen. The nitrogen is introduced from the container 26 through a line 20 into the upper region of the container 2o, so that the liquid hydrogen peroxide is continuously pressed into the line 22. The line 22 has a flow control valve 3o which, in its open position, allows liquid hydrogen peroxide to flow from the container 2o through the injection nozzle 24 into the combustion chamber 16. In this way in the combustion chamber 16 reached water

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Peroxide becomes exothermic to form a hot mixture of water vapor and oxygen decomposes, and this mixture reaches a temperature of about 700 C. This exothermic decomposition of hydrogen peroxide is through a catalyst 32, for example a material based on silver, which immediately is arranged in front of the injection nozzle 24, accelerated.

Through the fuel supply device 18 into the combustion chamber 16 imported fuel is burned by the "warning of hot oxidizing gases, so that in the combustion chamber 16 fuel gases are generated. The temperature of the oxidizing gases of about 700 C is sufficient to keep the Combustion of the fuel without causing any ignition devices.

The fuel gases produced in this way cannot usually be used as working media because they are too high in temperature of about 2,000 ° C. to 2,300 ° C. and have a relatively small volume. According to the invention, the hot combustion gases are therefore diluted with an additional fluid, so that the temperature of the working medium is reduced to a suitable value and, at the same time, the total volume
of the work equipment is increased to a value suitable for the intended use. Atmospheric air can be suitable as an additional fluid for diluting the fuel gases;

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however, water is because of its latent heat of vaporization and because for injecting a sufficient amount of air into the combustion chamber, if air is used as the additional fluid a pump or blower of considerable capacity is required.

A combustion device according to the invention
Therefore, there is also a supply device for an additional fluid with a water storage container 34.
A water supply line 36 leads from the bottom of the water container 34 via at least one water injection nozzle 38 to the combustion chamber 16. The outflow of water from the container 34 takes place either by its own weight or, if desired, by a pump 4o in the line 36 between the container 34 and the injection nozzle 38. The amount of water that is injected into the combustion chamber 16,
is controlled by a flow control valve 42 between the pump 4o and the injector 38. Water injected into the combustion chamber 16 is rapidly evaporated and mixed with the combustion gases generated by the oxidation of the fuel from the fuel supply device 18. The working medium thus formed is discharged from the combustion chamber 16 through an outlet 44 in the combustion cylinder 14.

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Some preferred embodiments of the combustion device 12 are shown in FIGS.

According to the preferred illustrated by FIG Execution sforin a combustion device 1 2 is a solid hydrocarbon fuel in the shape of a stick is used. A solid fuel rod can be made of plastic waste, such as plastic containers, are produced, so that not only results from the burning of hydrocarbons resulting air pollution but also prevent the accumulation of waste plastic products.

A solid fuel rod 46 is formed in one adjacent to the combustion chamber 16 in the combustion cylinder 14 Fuel chamber 48 held. The solid fuel 46 is axially displaceable in the fuel chamber 48 and its front surface 46a faces the combustion chamber 16. The combustion cylinder 14 has at one end the combustion chamber 16 has a projection 5o. A bore 5oa in the projection 5o is at one end via an inlet opening 52 at the inflow end of the combustion cylinder 14 and a line 22 with a hydrogen peroxide container 2o (Fig. 1) in connection. The other end of the bore 5oa is connected to a hydrogen peroxide injection nozzle 24 the combustion chamber 16 in connection. Inside the hole 5oa

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there is a catalyst 32, so that liquid hydrogen peroxide, which enters the bore 5oa from the line 22, is exothermic decomposed and thereby -from water vapor and Oxygen forms existing hot oxidizing gases. The so generated hot oxidizing gases are then through the Injector 24 is injected into the combustion chamber 16 and hits the front surface 46a of the solid fuel 46 in the fuel chamber 4d, so that on this front surface 46a, the solid fuel 46 is burned. The resulting large amount of hot fuel gases is with Water, gas from the water injection nozzle 38, which is connected to the water tank 34 via a line 36 (Fig. 1) is injected, mixed. The gases thus obtained have a sufficiently low temperature and a large enough volume to carry energy to a heat engine and are discharged through an outlet 44.

In order to protect the combustion cylinder 14 from the heat of the combustion gases, the combustion chamber 14 can preferably be lined with a layer 54 made of a heat-resistant material such as porous ceramic, porcelain or a sintered alloy. Instead of a single water injection nozzle 3a, the combustion device 12 can also have two or

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more water injectors 38 in communication with container 34 stand, be equipped.

The solid fuel 46 is steadily guided against the combustion chamber 16 so that its front surface 46a is constantly is exposed to oxidizing gases introduced into combustion chamber 16 through injector 24. In order to achieve this, the combustion cylinder 14 is provided with a tubular extension 56 protruding from an outer end of the combustion chamber 48. The tubular extension 56 has a bore 56 a, the with its inner end with the fuel canister 48 is in communication. An axially displaceable piston rod 5b extends, passes through the bore 56a and extends with its innermost end into the fuel chamber 48. The piston rod 58 carries at its inner end a contact part 6o which is in contact with the rear surface of the solid fuel 46 and is arranged axially displaceably in the fuel chamber 48. uie piston rod 58 also has a at its outer end Roller 62 in the bore 56a of the tubular extension 56 axially is movable. The bore 56a of the tubular extension 56 is at its end facing away from the fuel chamber 48 via a Passage 64 with a source for a hydraulic medium (not shown), which can be an air pump or that in the water tank 34 (Fig. 1) located water can use, in connection, pressure exerted by this pressure source acts on the outer surface 62a of the roller 62, such that the piston rod

-rf- ^v

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58 pushed against the solid fuel 46 and thereby the solid fuel 46 is continuously guided against the combustion chamber 16, to the extent that the solid fuel 46 is at its Front surface 46a is burned and consumed. To prevent, that the solid fuel enters the combustion chamber too quickly 16 can progress between the Brennkavtuner 16 and of the fuel chamber 48 is an annular inwardly projecting one Stop 66 may be provided so that the end surface 46a of the solid fuel 46 is mechanically restrained. As not shown, the combustion cylinder 14 is designed in such a way that that access to the fuel chamber 48 for insertion a solid fuel rod 46 or a rod that is consumed by normal combustion is to replace.

In a further preferred embodiment of a combustion device 12 illustrated by FIG. 3 a solid hydrocarbon fuel from generally Rohrforra is used. The tubular fuel 58 has a Longitudinal bore 28a and is displaceable, preferably via a heat-resistant lining 7o in a combustion cylinder 14 included. The peripheral surface of the bore 48a in the tubular fuel 68 delimits a combustion chamber 72, which at one end via an injection nozzle 24 at the inflow end of the combustion cylinder and a line 22 with a hydrogen peroxide container 2o (Fig. 1) in connection ~

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dung stands. The other end of the combustion chamber 72 is in open communication with a mixing chamber 74, which is in the outflow end of the combustion cylinder 14 is formed. Hot oxidizing gases from the exothermic decomposition of Hydrogen peroxide are injected into the combustion chamber 72, so that the solid tubular fuel 68 is on the surface its longitudinal bore 28a, which delimits the combustion chamber 72, is burned. The hot combustion gases generated in this way then pass into the mixing chamber 7 4.

In a wall at the end of the combustion cylinder 14 is a water distribution passageway surrounding the mixing chamber 74 76 formed, which has a number of holes 7tf in a wall part between the chamber 76 and the mixing chamber 74 are formed and evenly distributed therein, with the mixing chamber 74 in open communication. the Water injection nozzle 38, which is connected to the water tank 34 via line 36 (FIG. 1), extends up to the water distribution passageway 76, so that water is pressed from the container 34 into the passageway 76 and distributed there and pressed into the fuel gases in the mixing chamber 74. The combustion gases are thereby on a Suitable temperature cooled and brought to a certain volume and then v / ground through an outlet 8o, the in the downstream end of the combustion cylinder 14 is discharged from the mixing chamber 74.

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Compared to that illustrated by FIG. 2, this combustion device 12 has a larger surface of solid fuel that is accessible for combustion and is therefore particularly suitable when a very large volume of combustion gases is to be generated.
That is to say, a combustion device with a combustion device according to FIG. 3 is of particular advantage when it is used in a heating engine which requires a rapid response to acceleration conditions and a high energy output at high loads.

FIG. 4 illustrates a third preferred embodiment of a combustion device 12 of the combustion device of FIG. 1. In contrast to the combustion device in FIGS. 2 and 3, the combustion device 12 of FIG. 4 a liquid or gaseous fuel, such as heavy oil or light oil, kerosene, gasoline or liquefied natural gas or hydrogen, is used. As in the combustion device 12 of FIG. 2, the combustion device 12 of FIG. 4 has a combustion cylinder 14 with an extension 5o which has a bore 5oa, and in this bore there is a catalyst 32, which prevents the exothermic decomposition of liquid
Hydrogen peroxide, which through an inlet 52 into the drilling

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tion occurs. The hot oxidizing gases enter combustion chamber 16 through injection nozzle 24. A fuel injection nozzle do protrudes into the combustion chamber 16 and is connected via a supply line 82 to a source (not shown) for a liquid or gaseous fuel, so that fuel can be continuously introduced into the combustion chamber. The fuel is ignited by the hot oxidizing gases introduced through the nozzle 64 into the combustion chamber 16, and the combustion gases formed are diluted with water which is fed through an injection nozzle 38 _r which via the line 36 with a water tank 22 (Fig. 1) in connection is, is injected into the combustion chamber 16. The combustion chamber 16 has a heat-resistant lining 54 for protection against the heat generated in the combustion chamber 16 during the combustion of the fuel. The working medium occurring at a suitable temperature and in a suitable volume is discharged from the combustion chamber through an outlet 44 which is formed in the combustion cylinder 14.

As mentioned above, the combustion of the fuel takes place in the combustion device according to the invention at a sufficiently high temperature and in the absence of nitrogen so that the out of the device Exiting exhaust gases are completely free of unburned hydrocarbons and carbon monoxide, the

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occur in the case of incomplete combustion of a fuel, as well as toxic nitrogen oxides, which occur in presence of nitrogen in the oxidizing gases. The ones that arise when the temperature is too high Combustion gases are diluted with water, so that the working fluid formed has a temperature and a volume which can be precisely and easily controlled by varying the amount of water supplied to them.

The working medium produced in a combustion device according to the invention can be used for heating Water in a boiler or the evaporator of a steam engine or used to supply the energy for a gas-powered heat engine, such as a gas turbine will.

FIGS. 5 through 7 illustrate preferred modes of using a combustion device according to FIG of the invention in a steam engine.

In the arrangement "illustrated by FIG. 5, a combustor 12 as shown in FIGS Figures 2 or 3, or a modification thereof may be used. The combustion unit 12 is from a hydrogen peroxide container 2o via a line 22 containing a flow control valve 3o can, supplied with liquid hydrogen peroxide. Rivers

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Siges hydrogen peroxide in the container 2o is steady from the container 2o by means not shown at a speed controlled by the flow control valve 3o introduced into the incinerator 12 after it exothermically to a hot one in the presence of a catalyst, for example a material based on silver Mixture of water vapor and oxygen is decomposed. The combustion gases generated during the combustion of the fuel are mixed with water from a suitable water (not shown) source is introduced into the combustion device 12, and the working fluid formed of predetermined Temperature and predetermined volume is determined from the combustion device 12 by one of a (not shown) outlet of the combustion device 12 continuing channel 34 > which is made of a heat-resistant material or is protected by such a material.

An evaporator device 86 has a housing 88 with a gas inlet 88a, which is with the channel 84 in the open Connection is, and an outlet 88b, which leads to the atmosphere via an exhaust pipe 9o. A heat exchanger pipeline 92 runs in turns through the interior of the housing 88. Through the pipe 52 water is over Feeding racks described below are guided and, as it passes through the pipe 92, by heat exchange with the from the combustion device 12 in the

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Housing ÖÖ entering / working medium converted into steam. The steam generated in this way flows through a pipe 94 into a steam expansion device 96, with its speed is controlled by a pressure regulating valve 98 in the pipe 94. The relaxation of the in the relaxation facility 96 introduced steam takes place adiabatically, so that energy to operate a device, such as a turbine, is produced. The turbine is not shown in detail, but only by the reference number 1oo, for the impeller stands, symbolizes. The expanded steam is released from the expansion device 96 through a conduit 1o2 in a condenser 1o4, in which the steam is cooled and converted back into water. The water produced in this way is fed through a pipeline 1o6 to a pump 1o8 and from there again via a pipeline 11o into the Heat exchanger tubing 92 in the evaporator device 86 pumped. The pump is operated by the expansion device 96 via a coupling shaft 112. Around To put the pump 1o8 from its idle state in steam, it is with starter means, which according to the drawing from a at the same time with the pump via suitable designated 116 Coupling means drawn engine 116 equipped. The clutch 116 is designed so that it engages when the machine is started from an idle state should, and decoupled when the shaft 112 is driven by the start-up of the expansion device 96.

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In this way, water in the pipe 92 is continuously converted into steam in the evaporator device 86 and can continuously drive the shaft 100 when hot working medium enters the housing 88 from the channel 84 and exits the outlet 83b therefrom. Exhaust gases emerging from the evaporator device 86 essentially consist of carbon dioxide and water vapor, so that they can be discharged to the atmosphere directly or through a heat exchanger 11d. The exhaust pipe 9o and the pipe 11o pass through the heat exchanger 118 in such a way that residual heat in the exhaust gases flowing through the exhaust pipe 9o is partially transferred to the pipe 11o and thus preheats the water to be introduced into the heat exchanger pipe 92 in the evaporator 36. The vapor from the expansion device 96 can either be vented to the atmosphere or, as mentioned, condensed and returned to the evaporator device 86.

The water used to dilute the combustion gases generated in the combustion device 12 does not have to be introduced directly into the combustion device 12, as described above, but can alternatively also be introduced into the housing 38 of the combustion device 86 in order to dilute the combustion gases there. As indicated by the dashed lines in Flg. 5

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As shown, such an arrangement may be one of the exhaust pipe the exhaust gas circulation line branching off from the evaporator device 86 12o on v / iron. This exhaust gas recirculation line * 12o ends in a Distribution chamber 122, aie around the inlet portion of the housing is formed, and stands over a number of holes or injection nozzles 124 in a wall part-1, which the inner surface the junction box 122 is confined to the interior of the housing in open connection. In the circulation line 12o is a throttle valve 126, a fan or a pump 12ü and a flow control valve 13o is provided so that the exhaust gases (which mainly consist of water vapor, but can also contain considerable amounts of carbon dioxide) means of the fan or pump 128 into the distribution chamber at a rate controlled by the control valve 13o 122 are directed.

When the exhaust gases to the evaporator 86 be recycled, carbon dioxide can be separated from them to the effect of the dilution of the combustion gases to increase. 6 illustrates a steam engine with an exhaust gas recirculation arrangement suitable for this.

i'ig. 6 illustrates a steam engine used in essentially corresponds to the embodiment illustrated by FIG. Corresponding parts are therefore identical Provided reference numbers. For circulating the exhaust gases is

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a condenser 132 is provided. An exhaust pipe 9o leads into the condenser 132 so that water vapor in the exhaust gases the evaporation device 86 condenses to liquid water will. This liquid water contains that contained in the exhaust gases emerging from the evaporator device 36 Carbon dioxide. The condenser 132 has an outlet which, via a passageway 134, leads to a separating device 136 leads, in which carbon dioxide is extracted from the mixture and vented through an outlet 138 to atmosphere. The water is then passed through a pipe 14o a water reservoir 142 and from there fed through a pipeline 144 to a pump 146. By the pump 146 The water is passed through a pipe 148 and a flow control valve 15o into a chamber 152 which is in a channel 84 between the incinerator 12 and the Evaporation device 86 is arranged, pumped. The chamber 152 has a water injection nozzle 154, which with the pipe 148 is in open communication, so that the toasser supplied by the pump 146 with a through the Flow control valve 15o is injected into chamber 152 at a controlled rate. From the incinerator 12 exiting hot combustion gases are diluted in this way with water as they pass through the chamber 152 flow, and the working fluid obtained in this way has a suitable temperature of, for example, 1,200 to 1,6oo C. and a suitable volume.

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The pump 146 that carries the water into the canoe 152 is pumped back by a steam release device 96 via a coupling shaft 156, which is connected to a shaft 112, which connects the expansion device 96 with a pump 1o8 in the steam bypass arrangement described in connection with FIG. 5, driven. To get the pumps 1o8 and 1o6 are to be started from a dysentery state in which the expansion device 96 is out of operation Starter means are provided which, according to FIG. 6, consist of a rotor 15ö and a clutch 16o. Through the coupling 16o the motor 15 is coupled to pumps 1oö and 146 when the expansion device 96 is out of operation, and disengages when the expansion device 96 is in operation.

The exhaust gas recirculation arrangement can, if desired, v / ie as can be seen from the above description, are in open communication with the combustion device 12. In this In this case, the water injection nozzle 154 can be inserted into the combustion chamber 16 of the combustion device 12 of FIG. 2 or FIG. 4 or into an annular water distribution channel 76 of a combustion device 12, as shown in FIG. 3.

As mentioned above, the decomposition of hydrogen peroxide causes the fuel to burn generates a large amount of via steam. This amount of water vapor is generated by injecting water into the

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Combustion gases are increased so that the working medium finally reaching the VeruaEipfereinrichtunyen 36 of the steam engines illustrated in FIGS. 5 or 6 contain a very large proportion of water vapor. the
from the combustion device 12 incurred working means can therefore be used directly as a drive means for a
Mechanical energy generating part of a machine can be used without using an evaporation device or other devices, such as a pump or a heat exchanger pipeline, which can be associated with such an evaporation device. A preferred embodiment of a steam engine with which this is possible is illustrated in FIG. 7.

The steam engine illustrated in FIG. 7
has a vapor expansion device 162 into which a channel 84 leading away from the combustion device 12 opens. The steam release device 162
has an outlet (not shown) which is in open communication via a passageway 164 with a condenser 132 of an exhaust gas circulation arrangement as described in connection with FIG. Combustion gases
from the combustion device 12 thus flow through
the channel 34 and through the chamber 152 in which they are with
Are mixed is injected through a nozzle 154 of water. In the chamber 152 and in the on this

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Chamber following part of the channel ö4 becomes a very large one Amount of steam generated in Geraisch with a considerable amount of carbon dioxide. This equipment is used in the steam expansion device 162 is inserted and adiabatically relaxed to be a mechanical power generating part (not shown) can drive and rotate an output shaft 166. The relaxed steam is via the passageway 164 fed to a condenser 132 and condensed there to form liquid water. The mixture of liquid Water and carbon dioxide are then fed to a separator 136 from which carbon dioxide is passed through an outlet 138 is vented to the atmosphere. The liquid water is then fed to a pump 146 via a water reservoir 142 and by means of this pump via a flow control valve 15o of the water injection nozzle 154 is pumped. A pump 146 is used during operation of the machine Via a coupling path 16Ü through the steam expansion device 162 and during the start-up of the machine via a coupling 16o by the motor 15ö operated.

Since the combustion gases emerging from the combustion device 12 are used directly as working media for Operation of the expansion device 162 can be used in a steam engine of this type

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steam device can be omitted, so that a steam engine / as illustrated by FIG. 7, has a relatively simple structure and size.

Fig. 6 schematically illustrates a preferred system in which the combustion of a fuel is carried out generated thermal energy is divided so that machine parts are driven independently of each other.

The system illustrated by FIG. 8 includes a gas powered combustion machine and a steam powered machines, indicated generally by the reference numerals 17o and 172, respectively. the Gas-operated device 17o essentially corresponds in its structure to a combustion device 12, as illustrated in Figures 2-4 and has a source 174 of liquid hydrogen peroxide and a source 176 for a fuel, which in this case is a liquid or gaseous fuel such as Kerosene, heavy oil, gasoline, or liquefied natural gas or hydrogen can be on. Liquid hydrogen peroxide is from the source 174 by means of a pump 173 through a flow control valve 10 a catalyst 182, for example a material based on silver. Hydrogen becomes exothermic at catalyst 182 decomposed, so that a hot mixture of water

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Steam and oxygen enter the combustion chamber 184. While the oxidizing gases are being generated, fuel from source 176 is simultaneously being used a pump 186 is supplied to the combustion chamber 184 via a flow control valve 183. In this combustion chamber wirci the fuel is mixed with the hot oxidizing gases flowing in from the catalytic converter 182 and burned so that hot combustion gases are generated in the combustion chamber 184. If desired, you can valves 18o and 188 via a common mechanism or some other connection can be controlled so that fuel and hydrogen peroxide enter the combustion chamber be fed in a certain ratio. The combustion gases generated are grounded through a gas passageway 192 in a gas expansion device 194 to a first mechanical part 196 of the system to operate. Exhaust gases from the vent 194 can be vented to the atmosphere through an exhaust pipe 198 will.

The device 172 operated with steam, on the other hand, has an evaporation device 2oo with heat exchange means, communicating with the gas passageway 192. The evaporation device 2oo is fed with water from a water storage tank 2o2 via a pump 2o4, so that water

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occurs converted into steam by the evaporator device 2oo will. The steam is then introduced into a steam expansion device »2o3 via a passage 2o6, uui to drive a second mechanical part 21 ο of the system. Relaxed steam is released from the relaxation device 2o8 introduced into a condenser 212, where it is condensed into liquid water, which is then transferred to the water reservoir 2o2 is returned. The two mechanical parts 196 and 21 ο can be turbine wheels with associated shafts. The shafts can operate a common output part or cooperating output parts, or they can operate output parts that act independently of one another.

If desired, a further heat exchanger 214 can be provided which provides a connection between the line 192 for combustion gas and the steam line 2o6. This heat exchanger 214 is the evaporator device 2oo downstream, so that steam emerging from the evaporator device 2oo is further heated before he gets into the steam expansion device 2oä.

An example of a practically usable system of this type is given below in connection with FIGS. 9 and 1o illustrated, with only the separation chamber 134, the evaporation device 2oo and the directly connected

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which parts are shown.

A combustion chamber 184 is delimited by a combustion cylinder 214. The combustion cylinder 214 has an inlet (no reference number), which via a catalytic converter 182 with a flow control valve 18o (Fig. 8) is in communication, and an outlet (no reference number) which merges into the gas transfer path 192 on. A fuel injector 26o leads from a flow control valve 188 (FIG. 8) into the combustion chamber 184 and projects into it into it. Fuel is introduced into the burning karamer 184 through the nozzle 216 and therein in the presence of a hot one Mixture of water vapor and oxygen produced by exothermic decomposition of hydrogen peroxide in the presence of the Catalyst 182 is generated, burned. The one in the combustion chamber 184 hot combustion gases generated pass through gas passageway 192 and in due course propel a mechanical one Part 176 (Fig. 8). An evaporator device 2oo has a container 218 into which a water reservoir 2o2 a water supply line 22o opens via a supply pump 2o4 (FIG. 8). The combustion cylinder 214 is arranged in the container 218 so that it is with the water, which continuously enters the tank 21Ö from the water storage tank 2o8, is in contact or is immersed in it, so that water in container 218 is converted to steam. The container 218 has a steam outlet at its upper end (no reference number), which leads to a steam passage v / eg

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2o6 leads so that from the hot water in the container 218 rising steam from an expansion device 2o8 is supplied and drives a mechanical part · · 21o of the system. About the 'evaporation of'water in the container 213, the combustion cylinder 214 has a number of heat exchange parts or fins 223 on its outer wall, and if desired, the combustion cylinder 214 can have an extension 224 extending from the Combustion chamber 184 extends to the combustion gas passage 192, be formed to the surface on which Water in the container 218 by combustion gases the combustion chamber 184 can be heated to enlarge. The extension 224 may have a number of tubes 216 through which water from the container 218 is passed will.

Combustion gases generated in the combustion chamber 1Ü4 initially have a temperature above 2,000 C, as above erv / ähnt. If the combustion gases are only used to operate a mechanical drive part of an energy system, such as a gas turbine, its expansion must be gradual using a complex energy conversion treatment mechanism, whereby thermal energy is lost, and the individual parts of the combustion device and the gas turbine have to be replaced by costly

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ge heat-resistant material protected or made of such a material. If, on the other hand, the thermal energy The combustion gases are only used to convert water into steam, which is then a mechanical part an energy system, such as a steam engine, must necessarily have a large heat exchanger device Dimensions are provided.

These problems are eliminated in the system illustrated by FIGS. 8, 9 and 1o because a Part of the thermal energy of the combustion gases for operating a gas-powered mechanical part of a Energy system and partly for generating steam to operate a danipf-operated mechanical part of a Plant is used by combustion cylinder and others related parts are continuously transferred by the transfer of heat from the combustion gases to the one with the Combustion cylinders are cooled in contact with water and therefore do not have to be protected by or made of heat-resistant materials.

The mechanical energy generated by the gas and steam powered devices can be either can be combined in order to drive a common part or fed to independently operated parts.

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When a hybrid system according to the invention as an energy source is used for a motor vehicle, the gas and steam powered parts can be geared or hydraulic means for torque conversion can be connected to the crankshaft of the vehicle. In this Case can hydrogen peroxide and fuel during of idling at reduced speed are supplied to the combustion chamber to reduce the amount of combustion gases to reduce. Under this condition, thermal energy from the combustion gases can mainly be be used to generate steam, so that the Motor vehicle is operated by the steam-powered part of the hybrid system at a relatively low speed. This helps solve the problems that with the leakage of hot exhaust gases and with the loud noise that occurs when a conventional gas turbine engine is used Equipped motor vehicle at low speed around a corner or over an intersection moves. In addition, since the hot oxidizing gases produced by the exothermic decomposition of hydrogen peroxide are a have a very high oxidizing effect on fuel, flames cannot escape from the combustion chamber and not even when the rate of supply of fuel and hydrogen peroxide is relatively low Values drops. This allows the idle speed an engine in a motor vehicle according to FIG

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Invention can be considerably lower than a conventional, operated with a gas or steam turbine
Vehicle. For starting or accelerating the vehicle
the feed rate of fuel and hydrogen peroxide can be increased rapidly so that combustion gases are generated at a greatly increased rate. Under these conditions, the vehicle is then operated by the gas-powered part of the hybrid system, in such a way that a delay caused by operating the vehicle with
could occur in a steam-powered system.

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Claims (11)

Claims f \ ■ ! 1- / combustion device, .characterized by: that they have a combustion chamber, a device for introduction a fuel in the Brennkaramer, a device for the introduction of hot oxidizing gases, which are generated by exothermic decomposition of water peroxide, into the combustion chamber and a device for introducing a further fluid into the fuel gases, such that a working medium of suitable temperature and volume is generated. 2. Combustion device according to claim 1, thereby characterized in that the device for introducing the hot oxidizing gases has a catalyst for exothermic Zer- * Conversion of hydrogen peroxide to the hot oxidizing ones Has gases. 3. Combustion device according to claim 1, characterized in that the fuel is in the form of a solid Fuel rod, one surface of which is continuously exposed to the gases is exposed in the combustion chamber. 4. Combustion device according to Anspi'uch 3, thereby characterized in that the device for introducing the fuel a piston that engages a surface of the solid fuel rod outside of the combustion chamber. 30 9 8 k 2/0 5 k 3 men, as well as means for pressing the piston in the direction of the combustion chamber. 5. Combustion device according to claim 4, characterized in that the fuel introduction device still has a stop adjacent to the combustion chamber to permit movement of the solid fuel rod in the direction of Limit combustion chamber. 6. Combustion device according to claim 1, characterized characterized in that the fuel is in the form of a solid tube with a cylindrical bore delimiting the combustion chamber Has. 7. Combustion device according to claim 6, characterized characterized as being downstream of the solid fuel pipe a mixing chamber which is in open communication with the bore of the tubular solid fuel, and further supply means for injecting further fluid into the mixing chamber for diluting and cooling the has combustion gases generated in the boiling. 8. Combustion device according to claim 7, characterized in that it has a distribution chamber surrounding the mixing chamber with a number of holes through which the distribution chamber is in open communication with the mixing chamber, 309842/0543 has, v / obei the device for supplying further fluid at least one protruding into the distribution chamber Nozzle for introducing the additional fluid into the distribution chamber, from which this fluid passes through the openings into the mixing chamber. 9. Combustion device according to claim 1, characterized in that the fuel is flowable and in the Combustion chamber is injected, as well as by means for Injecting the liquid fuel into the combustion chamber. 10. Use of a combustion device according to one of claims 1 to 9 for generating a working fluid for heat engines. 11. Use of a combustion device according to one of claims 1 to 9 for the generation of the working equipment for a hybrid system with one .with gas and one with steam facility to be operated for iotor vehicles. 3098 4 2/054 3