NL2000189C2 - Reaction turbine with generator. - Google Patents

Description

Reaction turbine with generator

The present invention relates to a reaction turbine comprising an inlet part and outlet part and a combustion chamber lying therebetween, which parts are arranged rotationally symmetrically about the axis of rotation of the reaction turbine and wherein one of those parts is arranged spaced apart from the axis of rotation, whereby between that part and that axis of rotation forms a space.

Such a reaction turbine is for instance known from PCT / NL 2004/00144 in the name of Micro Turbine Technology B.V. It will be understood, however, that other reaction turbines can also be used in combination with the generator according to the present invention.

Such reaction turbines can be provided with a combustion chamber or other expansion part for, for example, steam, compressed air and the like. In many cases, it is contemplated to couple such a reaction turbine to a generator for generating electricity. The output shaft of the reaction turbine is thereby connected to the input shaft of the generator. These are arranged lying apart from one another in the direction of that axis with respect to each other. Combustion chamber is here understood to be a space where pressure increase takes place in any way (even without combustion).

The object of the present invention is to provide a more compact design for reaction turbine and generator.

This object is achieved with a reaction turbine described above in that a part of an electric generator is arranged in that space. A reaction turbine will generally run at high speeds (10,000-100,000 revolutions per minute). It has been found that a generator running at the same speed can be made small. This applies in particular to generators where permanent magnets are used. Due to the small volume of such generators, a part of such a generator can be accommodated in the space of the turbine wheel of such a reaction turbine. This is preferably the space that is formed by the combustion chamber of at least one component that extends parallel to the axis of rotation of the turbine. The generator can thereby be wholly or partially accommodated within that space. In addition, numerous options are possible for the design of the generator. It is thus possible to design the rotor lying outside and the stator lying inside lying out of 2. In such a case, the rotor is preferably connected directly to the turbine wheel. The stator comprising a coil lies substantially on the imaginary axis of the turbine wheel. It is also possible to choose an embodiment in which the rotor is arranged internally on the turbine shaft while the stator extends at least partially in the space between the rotor and the turbine wheel.

In all cases, thermal separation between the turbine wheel and the generator located inside can be provided. This thermal separation can comprise an insulation material, whether or not in combination with a cooling circuit.

Instead of the generator with magnets in the rotor mentioned here, any other generator known in the prior art can be used.

The invention also relates to a heating system in which the reaction turbine described above is used. Such a heating system can comprise a high-efficiency boiler. The reaction turbine is included in or near such a heating boiler and the heat derived therefrom is used for heating water or other heating medium. The generated electrical energy can be used at the location where the boiler is installed or delivered back to the grid.

In particular, such a reaction turbine with generator is attractive when used in combination with a hot water preparation part. After all, hot water will be required all year round so that such a reaction turbine can be effectively effective all year long.

If the reaction turbine is operated with a gas, it may be desirable to inject water into it in order to increase the efficiency, capacity, cooling of the structure and / or promote combustion. In the embodiment in which a high-efficiency boiler is used, this water can be the condensate water that results from the condensation of the flue gases from such a high-efficiency boiler.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing. In the following: FIG. 1 schematically shows a reaction turbine according to the present invention in front view;

FIG. 2 the reaction turbine according to FIG. 1 in cross section;

FIG. 3 a variant of the reaction turbine according to FIG. 2; and 3

FIG. 4 is a sectional steam turbine reaction turbine.

In Fig. 1, a reaction turbine is indicated by 1. This consists of a compressor wheel or turbine wheel 2. Fig. 2 shows that it is provided with an inlet opening 3 for, for example, air and a subsequent compressor part. 5 is followed by a combustion chamber 4, followed by an upstream expansion wheel 5 with jet nozzles 6. According to an advantageous embodiment of the invention, the combustion chamber 4 is designed as a continuous ring. However, it is to be understood that it is also possible to provide a number of combustion chambers, for example to provide as many combustion chambers as inlets 3 and jet nozzles 6 are present.

A combustible mixture is realized in the combustion chamber 4, which is ignited via spark plug 22. The combustion can then sustain itself. With such a turbine, a high-speed shaft 10 can be realized. Such a turbine is particularly suitable for the generation of small powers, on the order of kilowatts, for the generation of electricity.

To this end, a generator 7 is present consisting of an outer rotor 8 and an inner stator 11. The rotor 8 is connected to the wall of the combustion chamber 4 and comprises a number of permanent magnets. Measures may optionally be taken to prevent heat transfer between these two parts, such as the application of insulation 26.

The stator 11 consists of a number of coils 12 wound around a can package and mounted on stationary shaft 10.

Fig. 3 shows a variant in which the generator is accommodated in space 28. The axis 10 of the turbine is thereby extended and permanent magnets 40 are arranged thereon. Stator 39 is fixedly connected to the world and arranged between the rotating combustion chamber 4 and the rotating magnets 40. This is provided with a number of coils 38.

Fig. 4 shows a variant of the invention in which the generator is accommodated in space 29 and in which a fluid such as a liquid from container 14 is introduced via suction pipe 13 into pump impeller 15. Subsequently, at 16 evaporation takes place through the externally supplied heat which is schematically indicated with arrow 17. The jet nozzles 18 then provide for the rotational movement of the turbine wheel. In this embodiment, just like in Figures 1 and 2, the rotor 20 is arranged lying adjacent to the 4 wall of the combustion chamber 16. However, in this case a space for cooling channels 21 is present between the rotor 20 and this wall. In this example, the stator is included in the center of the structure and is indicated by 24 and comprises coils 25.

The turbines shown here can be arranged with their axis of rotation 10 in any desired position. Moreover, they have many applications. One of the applications is the use in a boiler which is either used to prepare hot water for a central heating system or used to prepare hot water for consumption purposes such as shower, bath, kitchen and the like. If all this is combined with a boiler in which the exhaust gases are subjected to a condensation step to recover the water (and heat) contained therein, the resulting water can be used for injecting into a fuel-driven turbine. As a result, the temperature in the combustion chamber can be lowered, reducing emissions.

15 Moreover, the return increases.

It has also surprisingly been found that the efficiency of the turbines shown here, i.e. reaction turbines, increases if the quality of the gas is poorer. That is, with a gas with a lower calorific value, the power does indeed decrease but not to an extent that could be expected, but to a lesser extent, which means that the efficiency actually increases. Therefore, the generators described above, in particular if they are not used in combination with primary heat-release systems such as central heating systems, can advantageously be used with a low calorific gas. The efficiency of the reaction turbine increases with the use of low energy outflow nozzles, the gas having a lower temperature and pressure. It should be understood that this method can be carried out independently of the measures described above.

After reading the above, further modifications will occur to those skilled in the art that are within the scope of the appended claims. In particular, rights are requested for the subject matter described in claim 1, but it is emphasized that separate rights are also requested for the subject matter of the subclaims.

Claims (10)

Reaction turbine (1, 19) comprising an inlet part and outlet part (6, 18) and an intermediate combustion chamber (4,16) which parts are arranged rotationally symmetrically about the axis of rotation (10) of the reaction turbine and wherein one of said parts spaced apart from the axis of rotation, so that a space (28, 29) is formed between that part and said axis of rotation, characterized in that part of an electric generator (7, 19) is formed in that space applied. Reaction turbine according to claim 1, wherein said combustion chamber comprises a combustion chamber. Reaction turbine according to one of the preceding claims, wherein a water injector is arranged in the combustion chamber of said turbine. 15 Reaction turbine according to one of the preceding claims, wherein the rotor of said generator is fixedly connected to the axis (10) of the reaction turbine. 5. Reaction turbine according to any of the preceding claims, wherein the rotating part of that generator comprises a permanent magnet (9.40). Reaction turbine according to one of the preceding claims, wherein an insulating partition wall (26) is arranged between said generator and that part. Reaction turbine according to one of the preceding claims, wherein a cooling channel (21) is arranged between said generator and that part. System comprising a heating boiler and a reaction turbine arranged therein according to one of the preceding claims. 30 9. System as claimed in claim 8, comprising a hot water preparation part, wherein heat originating from said reaction turbine is supplied to said hot water preparation part. System according to claim 8 or 9 in combination with claim 3, wherein said boiler is an Hr boiler and the condensate part thereof is connected to said water injector.