ES2739725B2 - COMBUSTOR FOR TURBINE AND TURBINE OBTAINED - Google Patents

Description

DESCRIPTION

COMBUSTOR FOR TURBINE AND TURBINE OBTAINED

Object of the invention

The invention relates to a turbine combustor, the purpose of which is to provide an increase in the pressure of the ignited mixture of air and fuel, in order to obtain an increase in revolutions, and thus provide a greater percentage of engine effort, allowing greater speed.

Furthermore, the invention relates to a turbine including the combustor.

Therefore, it is applied in vehicles that require the use of a turbine as a means of propulsion, and more specifically in aircraft and drones.

Background of the invention

In the state of the art, the use of a gas turbine is known, which is a driving machine that converts the energy derived from the combustion of an element, normally kerosene, into mechanical energy in the form of a high-pressure, high-temperature air jet. .

This mechanical energy can be harnessed to move a propulsion mechanism such as an airplane propeller or helicopter rotor, or to generate the thrust that propels an aircraft.

For this, gas turbines comprise a compressor, a combustor, an air direction element, a turbine rotor and an exhaust manifold.

The compressor has an air inlet duct, which is equipped with a series of rotors that displace the air, so that each one of them produces an increase in air pressure, obtaining a progressive pressure increase, from the first rotor , which receives the air, to the last rotor that drives the compressed air towards the combustor.

In the combustor a constant flow of fuel is applied in the form of spray, steam or both, so that by means of heat it burns at an almost constant pressure, which when ignited produces the violent expansion of gases in the form of a high pressure jet, to which the pressurized air coming from the compressor joins, forming a pressurized mixture that impacts against the blades of the turbine rotor, which it makes rotate at more than 10,000 RPM The axis of rotation of the turbine rotor is shared by the compressor, so that the rotor of the turbine also drives the compressor to increase air pressure. To mix the air from the compressor with the combustion gases, the combustor is provided with a casing that is equipped with a series of holes through which the pressurized air from the compressor enters and mixes with the combustion gases. . The pressurized air mixture with the pressurized gases obtained is applied to a directing element that guides the mixture in the direction of the turbine rotor blades so that said mixture impacts perpendicularly on the turbine rotor blades, and thus favoring its rotation. This configuration has the drawback that the mixture of combustion gases with pressurized air hits the directing element to change its trajectory and orient it in the direction perpendicular to the rotor blades, which entails a loss of energy. and thrust that subtracts pressure from the turbine when the mixture collides against said directing element, reducing the performance and speed of the turbine.

Finally, this jet of gases is expelled into the atmosphere through an outlet nozzle.

The invention provides a new turbine combustor that solves the aforementioned problems, eliminating the casing with the holes through which the pressurized air from the compressor enters, and arranging the combustion chambers with an inclination facing the rotor blade of the turbine. turbine, at whose outlet the directing element is arranged, so that the combustion gases are already directed in the direction of the turbine rotor blades, and mix with the pressurized air in the directing element, impacting the It mixes perpendicularly, in an ideal way, against the blades of the turbine rotor, which prevents the combustion gases from impacting against the directing element, avoiding the consequent loss of thrust and increasing the pressure in the turbine, so that it is obtained higher efficiency and speed of the turbine.

Description of the invention

In order to achieve the objectives and solve the aforementioned drawbacks, the turbine combustor of the invention presents as its main novelty that it is characterized in that it comprises a plurality of combustion chambers attached in an annular configuration and with an inclination oriented according to the inclination of the blades. of the turbine rotor, to provide a perpendicular combustion outlet facing said blades; the outlet of each combustion chamber being delimited laterally by inclined partitions with the same inclination as the blades of the turbine rotor, and parallel ending in proximity to said blades of the turbine rotor. Besides, the The invention comprises at least one fuel distribution element provided with a fuel inlet and a plurality of fuel outlets, each connected to a combustion chamber. By means of this configuration, the air coming from the compressor is mixed with the combustion of each chamber in the zone delimited by the parallel inclined partitions.

The fuel distribution element comprises a single fuel inlet and a fuel outlet for each combustion chamber, the distribution element being arranged concentrically and with a smaller radius, following the annular structure formed by the combustion chambers, so that each combustion chamber is connected to a fuel outlet of the distribution element, to distribute the fuel to each of the combustion chambers.

In the preferred embodiment of the invention, the inclination of the combustion chambers is 33°, coinciding with the angle normally formed by the blades of the turbine rotor.

The combustion chambers comprise an upper threaded hole in which an electrical terminal is arranged that includes a heating wire through which the combustion of the fuel in the corresponding combustion chamber is caused. The thread is preferably nichrome.

The invention foresees that the electrical terminal is arranged in the combustion chamber by means of a jacket in which it is retained.

The inclined partitions are attached to an outer ring by means of which the combustor is fixed inside the turbine, for which said outer ring comprises a series of holes through which it is fixed to the turbine, for example by means of screws.

In one embodiment of the invention, the combustion chambers are connected to a single fuel pump with adjustable pressure, so that by regulating its pressure, the speed of the turbine rotor is governed automatically.

In another embodiment of the invention, the combustion chambers are grouped according to a number of chambers equidistant from each other, so that each group of combustion chambers is connected to a fuel distribution element, which in turn, each of said fuel distribution elements are connected to a different fuel pump, so that depending on the number of fuel pumps that are activated, the speed of rotation of the turbine shaft is regulated.

In the preferred embodiment of the invention, it is foreseen that it comprises twelve combustion chambers, with which groupings of 2, 3, 4 or 6 combustion chambers can be established, each of them connected to a fuel distribution element, at its time, each of them connected to a different fuel pump to regulate the speed of rotation of the turbine shaft depending on the number of fuel pumps that are activated.

Furthermore, the invention relates to a turbine including the combustor described above.

Description of the figures

To complete the description and in order to help a better understanding of the characteristics of the invention, a set of figures is attached to this description, as an integral part of it, in which, for illustrative and non-limiting purposes, it has been represented the next:

Figure 1 shows a side view of the turbine with the combustor.

Figure 2 shows a perspective view of the combustor of the invention from its rear.

Figure 3 shows a perspective view of the combustor of the previous figure from its front part.

Figure 4 shows a perspective view of the fuel distributor included in the combustor of Figures 2 and 3, which feeds the different nozzles in which combustion occurs.

Figure 5 shows a perspective view of the configuration of a nozzle, the interior of which has been shown in dashes.

Figure 6 shows an exploded view of the elements that make up the electrical terminal of the mouthpiece.

Preferred embodiment of the invention

A description of the invention is made below based on the aforementioned figures.

The combustor 2 for turbines 1 of the invention, as in the state of the art, is arranged after a compressor 3, which absorbs the air from outside the turbine 1 and drives it to combustor 2.

As is known, the compressor 3 comprises a series of rotors 4, each one of which displaces the air, progressively increasing its pressure, from the first rotor 4, which receives the air, to the last rotor 4 which drives the air. compressed to combustor 2, so that the air reaches a pressure between 10 and 40 times greater than the pressure of the air entering the compressor.

The combustor 2 has a novel configuration that comprises a plurality of combustion chambers 5 back-to-back forming an annular structure 6, concentric to which and with a smaller radius, it comprises a fuel distributor 7, also with an annular configuration, on whose rear face it includes a fuel inlet 9, connecting to a fuel tank (not shown), and on its outer side face, comprises a fuel outlet 8 for each combustion chamber 5, to provide fuel to each of said combustion chambers. combustion 5. The connection of the distributor 7 with the fuel tank is made through one or more pumps, as will be explained later. The fuel used is generally kerosene.

In the preferred embodiment of the invention, the number of combustion chambers 5 is twelve to allow the speed of the turbine rotor to be adjusted, as will be explained later.

Each of the combustion chambers 5 comprises a casing 10 provided with a fuel inlet hole 11 and including an inclined interior configuration, with an inclination equal to that of the rotor blades 12 of the turbine 1, and comprising a Inclined threaded upper hole 13 and an inclined outlet nozzle 14. The inclinations are all the same, although the important one is that of the outlet nozzle 14, which must be equal to the inclination of the rotor blades 12 of the turbine 1, in order to that the gases strike perpendicularly on said blades. In the upper threaded hole 13 a sleeve 15 is retained, which is arranged with the inclination of the upper hole 13, and which includes a fuel inlet hole 16 and in which an electrical terminal 17 is retained in the inclined position and which is configured to house inside it a wire 18, preferably nichrome, which, when an electrical voltage is applied, heats up producing combustion that causes the violent expansion of the gases produced in the form of a high pressure jet with the inclination of the rotor blades 12 of the turbine, on which it strikes perpendicularly to produce the rotation of the rotor blades, ideally. The entry of fuel into the jacket 15 is carried out with a constant flow in the form of spray, steam or both, and is burned at almost constant pressure. The preferred angle of the blades and exit of the combustion chambers 5 is 33°, equal to that of the blades of the rotor 12 of the turbine 1.

Compressor 3 shares a shaft 19 with the turbine rotor 12, so that part of the energy of the jet makes the rotors 4 of compressor 3 rotate at more than 10,000 R.P.M. By influencing the combustion gases perpendicularly on the turbine rotor blades, the propulsion generated by combustion is used to the maximum, which provides greater performance compared to the state of the art, in which part of the energy is wasted. energy produced in combustion, as already mentioned.

In addition, the combustor 2 comprises, at the outlet of the combustion chambers 5, a directing element made up of inclined partitions 20, and arranged with the inclination of the jackets, forming inclined corridors oriented according to the inclination of the rotor blades 12 of the turbine 1, which laterally delimit the outlet of each of the combustion chambers, so that the pressurized air from the compressor 3 runs outside the combustion chambers 5 and mixes with the high pressure jet produced by the combustion in the areas delimited by the inclined partitions 20. This configuration ensures that said mixture directly affects the turbine rotor blades 12 perpendicularly, and by adding the gases directly with the inclination of the turbine rotor blades, and not encountering obstacles, a greater thrust power or pressure is obtained, achieving an increase in the speed of rotation of the blades, which makes it conv It relies on a more powerful engine, which has the ability to rev very quickly, reacting quickly when maneuvering and achieving greater stability.

On the outer side of the inclined partitions, it comprises an element for fixing the combustor inside the turbine casing 21, preferably constituted by a perimeter ring 22 that is provided with a plurality of fixing holes 23 by means of screws inside the the casing 21 of the turbine 1.

The number of combustion chambers 5 in which the combustion is carried out, allows various gears or engine times to be obtained. Thus, in this example, by comprising twelve nozzles 14, it allows the engine to work by carrying out combustion in three, six, nine or twelve combustion chambers 5 simultaneously, evenly distributed, which is equivalent to being able to work with four different gears .

For this, in one embodiment of the invention the use of four pumps of each of which is connected to a fuel distributor through its fuel inlet 9, and which in turn are provided with three fuel outlets 8, instead of twelve. Each of the outlets 8 is connected to a combustion chamber 5; which allows a first operating gear to be obtained by activating a single pump, producing combustion in three of the combustion chambers. In the same way, a second gear can be obtained by simultaneously activating two pumps, which produces combustion in six of the combustion chambers. A third gear can also be provided by driving three pumps simultaneously, with combustion taking place in nine combustion chambers, or a fourth gear can be applied by driving all four pumps while producing combustion in all twelve chambers. Each of the pumps that is activated absorbs the fuel from the tank and pushes it towards the distributor to which it is connected, where it enters through inlet 9 and is distributed through outlets 8 to the three nozzles to which they are connected.

According to the above, it is easily understood that instead of providing a four-speed turbine, a three-speed turbine can be obtained, for which in this case three fuel pumps and three fuel distributors with one inlet and four outlets are used. each one, connected to the corresponding combustion chambers, so that by activating a single pump, two, or all three at the same time, the speed of the turbine can be regulated by means of one, two or three gears, respectively.

Equivalently, two fuel pumps and two distributors can be used, each with six fuel outlets, allowing two gears to be obtained; a first gear activating a single pump or a second gear activating the two pumps at the same time.

The distributors of the previous cases are arranged concentrically to the annular structure 6, in such a way that they allow the mentioned functionality to be carried out.

It can also work with a single gear by using a single fuel pump, which sucks the fuel from the tank and pushes it towards the distributor 7, where it enters through the inlet 9 and is distributed through the outlets 8 to the 12 nozzles. injection, with a pressure dictated by a flow regulator or electric potentiometer, which speeds up or slows down the fuel pump. Therefore in this case there is a single gear whose acceleration is regulated by the rotation control of the only pump it has.

By means of the described configuration, stability, precision and fast response of the engine are achieved due to the injection nozzles that are placed in such a way that they impact on the turbine blades without obstacles, with an ideal inclination (33°) and in the ideal part of the shovel

In any of the cases, the distribution of nozzles is carried out in such a way that they are arranged equidistant from each other, preventing oscillations or vibrations from occurring on the axis of rotation.

The configuration described also allows gear changing to be done manually or automatically. Automatic changeover is achieved by operating all twelve nozzles at the same time and regulating pressure on a single fuel pump, rather than four pumps.

Manual gears are obtained by making all three, six, nine or twelve combustion chambers work by activating their corresponding pumps.

Furthermore, the invention relates to a turbine including the combustor described above.

Claims (12)

1. - Turbine combustor, which receives pressurized air from a compressor (3), characterized in that it comprises: - a plurality of combustion chambers (5) attached according to an annular configuration (6) and with an inclination oriented according to the inclination of the rotor blades (12) of the turbine (1), to provide a combustion outlet perpendicular to said Pallas; the outlet of each combustion chamber being delimited laterally by - some partitions that form inclined corridors (20) provided with the same inclination as the blades of the rotor (12) of the turbine and parallel, which end in said blades of the turbine rotor, - at least one fuel distribution element (7) provided with a fuel inlet (9) and a plurality of fuel outlets (8), each connected to a combustion chamber (5); to distribute the fuel to each of the combustion chambers (5); where the air coming from the compressor (3) mixes with the combustion of each chamber in the area delimited by the partitions that form parallel inclined corridors. 2. - Turbine combustor, according to claim 1, characterized in that the fuel distributor (7) is arranged concentrically and with a smaller radius following the annular structure (6) formed by the combustion chambers (5). 3. - Turbine combustor, according to claim 1, characterized in that the inclination of the combustion chambers is 33°. 4. - Turbine combustor, according to claim 1, characterized in that the combustion chambers (5) comprise an upper threaded hole (13) for the arrangement of an electrical terminal (17) that includes a heating wire (18) 5. - Turbine combustor, according to claim 4, characterized in that the heating wire is made of nichrome. 6. - Turbine combustor, according to claim 4, characterized in that the electrical terminal (17) is arranged in the combustion chamber by means of a jacket (15) in which it is retained. 7. - Turbine combustor, according to claim 1, characterized in that the partitions that form inclined passageways (20) are attached to a perimeter ring (22) for fixing the combustor inside the turbine. 8. - Turbine combustor, according to claim 7, characterized in that the perimeter ring (22) for fixing the combustor in the turbine comprises a series of holes (23) for fixing it to the turbine. 9. - Turbine combustor, according to claim 1, characterized in that the combustion chambers (5) are connected to a single adjustable pressure fuel pump to govern the speed of the turbine rotor automatically. 10. Turbine combustor, according to claim 1 or 2, characterized in that the combustion chambers are grouped according to a number of chambers equidistant from each other, where each group of combustion chambers is connected to a fuel distribution element (7 ), which in turn, each of said fuel distribution elements is connected to a different fuel pump to regulate the speed of rotation depending on the number of activated fuel pumps. 11. - Turbine combustor according to any of the preceding claims, characterized in that it comprises twelve combustion chambers. 12. - Turbine comprising the combustor of any of the preceding claims.