DE19631473C2 - Internal combustion engine - Google Patents

Description

The invention relates to an internal combustion engine according to the preamble of Claim 1.

In such an internal combustion engine, as described in DE 195 01 192 A1 is known and in their combustion chambers fuel with liquefied oxidation is burned medium, there is a very high energy density in very small Combustion chambers because in addition to the expansion of the combustion gases Expansion of the evaporating oxidizing agent is added. This leads to a considerable material stress and thus an impairment of life duration of the internal combustion engine.

In the Brenn known from US 5 282 356 and US 5 408 824 In contrast, a fuel / air mixture is burned in engines. Here occur much less compared to the generic internal combustion engine lower combustion temperatures. To reduce the material load is  in US 5 282 356 a water cooling surrounding the combustion chamber seen, while in US 5 408 824 the combustion chamber in an outer Ceramic shield is arranged. With such external cooling equipment the material load of the generic internal combustion engine but not to a desirable extent. Furthermore, the combustion energy in both cases to promote the evaporation and ejection of thrust Water used. In US 5 282 356 are in the area of the Combustion chamber adjoining, open to the circumference of the rotor cutout the rotor nozzles are provided, through which water thrust from the Water cooling is ejected. In US 5 408 824 water is over Tubes injected into the interior of the combustion chamber, evaporated there and together men with the combustion products. The discharge of water serves primarily to increase the output mass and thus a more efficient Converting the combustion energy into kinetic energy. As a side effect cooling of the combustion chamber.

The object of the invention is to provide an internal combustion engine according to the Preamble of claim 1 to create, in which the material load in the area the combustion chambers can be significantly reduced.

This task is performed according to the characteristic part of the Claim 1 solved.  

Because the combustion by introducing water or by Enlarging and filling the combustion chambers can cool the energy density in the combustion chambers and thus the temperature of the material of the Combustion chambers exposed to be significantly reduced.

In particular, liquid oxygen, but also, for example, liquefied air highly enriched with oxygen be set. The former has the advantage that there is practically no combustion Nitrogen oxides occur. The fuel is petrol, diesel oil, rapeseed oil or same as biologically produced oil, coal dust or gaseous fuel questionable.

Further embodiments of the invention are described below exercise and the subclaims.

The invention is described below with the aid of an illustration in the appended tion illustrated embodiment explained in more detail.

Fig. 1 shows an internal combustion engine in axial section.

FIGS. 2 to 4 show various embodiments of combustion chambers for internal combustion engine of FIG. 1,.

Fig. 5 shows the internal combustion engine of Fig. 1 in a composite.

The rotary rocket motor shown in FIGS . 1 and 2 comprises a rotor housing 1 which has a chamber 2 and is preferably formed from a plurality of disks 3 a, 3 b, 3 c, 3 d (see FIG. 2).

In the chamber 2 , a preferably disc-shaped rotor 4 is angeord net, which carries an output shaft 5 which is mounted in the rotor housing 1 and is guided on one side to the outside. The rotor 4 has a plurality of combustion chambers 6, four in the exemplary embodiment shown, arranged at a uniform distance from one another, adjacent to its outer circumference. Each combustion chamber 6 is connected via an in particular laval nozzle-like outlet opening 7 to a cutout 9 of the disk-shaped rotor 4 which is open in the direction of rotation (arrow 8 ) and is open towards the circumference of the rotor 4 . Each section 9 has expediently in side view of the rotor 4 substantially in the form of a right triangle triangle, the longer catheter preferably continuously merges into the outer circumference of the rotor 4 .

As can be seen from Fig. 1, the rotor 4 can consist of three mutually braced disks 4 a, 4 b and 4 c, the outer disk 4 c being integrally connected to the output shaft 5 .

The rotor 4 is surrounded on its outer circumference by an Abgassammelka channel 10 of the width of the rotor 4 (plus little play on both sides), which is open to the rotor 4 and from a narrowest point, where there is only play between the rotor housing 1 and the rotor 4 be, up to a nozzle 11 of an exhaust gas discharge line in its cross section continuously enlarged to the cross section of the nozzle 11 . As a result, the cutouts 9 are in direct connection with the exhaust gas collecting duct 10 .

The central supply of liquefied oxidizing agent and fuel takes place via a distributor 12 which is fixedly connected to the rotor housing 1 and is arranged coaxially to the axis of rotation of the rotor 4 and extends approximately to the center thereof. The distributor 12 has a central channel 13 for the liquefied oxidizing agent and a channel 14 surrounding this ringför shaped for fuel. In the rotor 4 a Lei device 15 or 16 for oxidizing agent or fuel is guided to the respective combustion chambers 6 , the lines 15 and 16 are correspondingly open to the distributor 12 . The distributor 12 has a distribution chamber 17 connected to the channel 13 for oxidizing agent on the lines 15 and connected to the channel 14 bores 18 which open into an annular channel 18 a, which is connected to the lines 16 , so that the combustion chambers 6 are supplied simultaneously become.

The distributor 12 can also be provided on the outer circumference with associated distribution openings, so that during operation the respective combustion chambers 6 are supplied with a predetermined amount of oxidizing agent and fuel in succession in a predetermined period of time.

The rotor housing 1 is expediently provided with cooling water spaces 19 . To the arbiter 12 around a cooling medium flowed through the cooling chamber 20 in the driven shaft 5 is provided. A cooling chamber 21 located in the rotor 4 is connected to the latter via bores 22 and receives the respective lines 15 , 16 . The lines 15 , 16 open into a distributor piece 23 inserted in the rotor 4 and surrounded by the cooling space 21 and receiving the end of the distributor 12 .

The cooling chamber 21 is connected via radial bores 24 through which lines 15 , 16 are led to the combustion chambers 6 , with annular cooling chambers 25 surrounding the respective combustion chambers 6 . From the respective cooling chamber 25 , several feed channels 26 lead into the entry region of the laval nozzle-like outlet opening 7 of the combustion chamber 6 . Cooling water is expediently metered according to the desired amount of water vapor into the combustion chamber 6 via a metering pump in order to be converted there into water vapor and thus at the same time to reduce the energy density there.

Furthermore, a metering pump 27 connected to a water reservoir, such as a speed-controllable gear pump, is provided, with which the fuel in the fuel feed 14 can be metered, preferably in substantially demineralized water. However, fuel as a mixture with water in a predetermined ratio can be taken up and fed into a tank.

The start-up is preferably carried out with pure fuel, to which water is then added up to, for example, a ratio of 1: 1, depending on the power requirement, as a result of which the energy density in the region of the combustion chambers 6 is correspondingly reduced with simultaneous steam generation.

Since the energy density during combustion in such a rotary rocket motor is very high, it can be used as a steam generator, the amount of steam generated being sufficient to operate a condensation turbine 28 which can, for example, operate a generator (not shown), cf. Fig. 5. At the same time, the carbon dioxide generated during combustion is largely dissolved in the water. The condensate and exhaust gas (carbon dioxide) coming from the turbine 28 can, if appropriate, be cooled with, in particular, alkaline cooling water at 29 and then passed into a receiving water 30 or the like, so that ultimately practically no carbon dioxide gets into the atmosphere.

As can be seen from FIG. 3, it may be expedient if the combustion chamber 6 contains a filling 31 made of open-pore material. The latter is expediently a granular ceramic material such as aluminum oxide or zirconium oxide. This material can optionally be combined into a single body by sintering. The filling 31 is arranged in the illustrated embodiment between two perforated plates 32 , 33 , fuel and oxidizing agent being supplied adjacent to the inlet-side perforated plate 32 outside the filling 31 , while the outlet-side perforated plate 33 supports the filling 31 at the entrance to the laval nozzle-like outlet opening 7 . The open-pore material of the filling 31 can have an increasing pore size in the direction of the outlet opening 7 .

Through the filling 31 , which stores heat and promotes a complete combustion, the amount of fuel to be burned is throttled, causing a cooling effect which lowers the combustion temperature. It results in a zone or at an interface of the porous material in the combustion chamber 6 corresponding to the pore size, a critical Péclet number for the ignition, above which ignition takes place.

In this way it is possible to use combustion chambers 6 with a considerably increased volume for the same output, which for example can be five times the size of the combustion chambers 6 of FIG. 2. The energy density can also be greatly reduced here.

According to FIG. 4, the outlet-side perforated plate 33 forms the off-opening 7 and the feeding channels 26 open out development in the field of fuel 31 just before the orifice plate 33.

If necessary, the rotor 4 can consist of ceramic material or can be provided with a ceramic coating 21 . The inner wall of the chamber 2 of the rotor housing 1 can be coated with ceramic material.

The rotary rocket engine can be operated such that the fuel and the oxidant all combustion chambers 6 simultaneously fed and burned after auto-ignition.

If the fuel ignites in (at least) one combustion chamber 6 , a corresponding expansion occurs in addition to the evaporation expansion of the liquefied oxidizing agent. The resulting gases emerge through the outlet opening 7 into the cutout 9 following this and thus also into the exhaust manifold 10 with acceleration of the rotor 4 in the direction of rotation. Due to the high exit velocity of the exhaust gases from the openings 7 , these are conveyed into the exhaust gas discharge line. Because of this, there is no need for a seal between the rotor 4 and the rotor housing 1 ; rather, there can be a relatively large clearance between them without this affecting the operation.

The combustion chamber 6 is formed in a combustion chamber insert 34 , which consists of several axially arranged sections 34 a, 34 b, 34 c and in a corresponding Sachlock boring of the ro tor 4 , which opens to the cutout 9 , inserted and from the cooling chamber mer 25 is surrounded. The combustion chamber insert 34 consists, for example, of zirconium oxide, which is stabilized with yttrium oxide and is suitable for temperatures up to 2500 ° C.

The output shaft 5 is gela via bearings 35 in the rotor housing 1 , which are lubricated via lubricating oil lines 36 .

Claims (14)

1. Internal combustion engine with a cylindrical chamber ( 2 ) having a rotor housing ( 1 ), a rotor ( 4 ) connected to a drive shaft ( 5 ) and rotating in the chamber ( 2 ), which is adjacent to its circumference at least one with a fuel supply ( 14 ) and a feed ( 13 ) for liquid oxidizing agent connectable combustion chamber ( 6 ), which via an outlet opening ( 7 ) in a direction of rotation of the rotor ( 4 ) subsequent to the circumference of the rotor ( 4 ) open cutout ( 9 ) of the rotor ( 4 ) opens, and with an exhaust gas discharge line ( 11 ) and water cooling, characterized in that a metering device ( 27 ) is provided for admixing water for fuel supply ( 14 ) and / or the combustion chamber ( 6 ) has a filling ( 31 ) made of open-pore ceramic material. 2. Internal combustion engine according to claim 1, characterized in that the combustion chamber ( 6 ) is surrounded by a cooling chamber connected to the water cooling ( 25 ), lead from the feed channels ( 26 ) in the outlet region of the combustion chamber ( 6 ). 3. Internal combustion engine according to claim 1 or 2, characterized in that the rotor ( 4 ) has a central cooling space ( 21 ) with which the cooling chambers ( 25 ) are connected. 4. Internal combustion engine according to one of claims 1 to 3, characterized in that the open-pore material of the filling ( 31 ) has an increasing pore size in the direction of the outlet opening ( 7 ). 5. Internal combustion engine according to one of claims 1 to 4, characterized in that the combustion chamber ( 6 ) is formed in a combustion chamber insert ( 34 ) for the rotor ( 4 ). 6. Internal combustion engine according to claim 5, characterized in that the combustion chamber insert ( 34 ) consists of several sections ( 34 a- 34 c). 7. Internal combustion engine according to one of claims 1 to 6, characterized in that the rotor ( 4 ) is disc-shaped. 8. Internal combustion engine according to one of claims 1 to 7, characterized in that the exhaust manifold ( 10 ) from only existing play continuously expanded until the cross section of the exhaust gas discharge is reached. 9. Internal combustion engine according to one of claims 1 to 8, characterized in that the exhaust gas discharge line is connected to the input side of a downstream steam turbine ( 28 ). 10. Internal combustion engine according to claim 9, characterized in that the steam turbine ( 28 ) is followed by an exhaust gas cooling ( 29 ). 11. A method for operating an internal combustion engine comprising a cylindrical chamber (2) having rotor housing (1), a part connected to a drive shaft (5), in the chamber (2) surrounding the rotor (4), adjacent to its periphery at least one a fuel supply ( 14 ) and a supply ( 13 ) for liquid oxidizing agent combustible combustion chamber ( 6 ), which has an outlet opening ( 7 ) in a subsequent in the direction of rotation of the rotor ( 4 ) subsequent to the circumference of the rotor ( 4 ) open cutout ( 9 ) of the rotor opens ( 4 ), and with an exhaust gas discharge line ( 11 ) and a water cooling system, characterized in that the fuel is fed to the combustion chamber ( 8 ) in a diluted manner with the water. 12. The method according to claim 11, characterized in that the force material is diluted with water up to a ratio of about 1: 1. 13. The method according to any one of claims 11 to 12, characterized in that cooling water is introduced into the combustion chamber ( 8 ). 14. The method according to claim 13, characterized in that the introduction of cooling water into the combustion chamber ( 8 ) is regulated via a metering pump.