CN112879178B

CN112879178B - Solid rocket ramjet based on detonation combustion

Info

Publication number: CN112879178B
Application number: CN202110090134.7A
Authority: CN
Inventors: 夏镇娟; 马虎; 侯世卓; 何勇
Original assignee: Nanjing University of Science and Technology
Current assignee: Nanjing University of Science and Technology
Priority date: 2021-01-22
Filing date: 2021-01-22
Publication date: 2022-11-04
Anticipated expiration: 2041-01-22
Also published as: CN112879178A

Abstract

The invention discloses a solid rocket ramjet engine based on detonation combustion, which comprises a shell, an inner core body, an air inlet channel, an isolation section channel, a detonation combustion channel, a fuel gas generator, a steady flow annular cavity, a main fuel injection system, a rotary detonation combustion chamber, a tail nozzle and other structures; an air inlet channel, an isolation section channel and a detonation combustion channel are formed between the inner wall of the outer shell and the outer wall of the inner core body; the air captured by the air inlet channel is subjected to deceleration and pressurization in the isolation section and then enters the rotary detonation combustion chamber; the front part of the inner core body is of a hollow structure, a fuel gas generator is arranged in the inner core body, the oxygen-poor solid propellant is combusted in the fuel gas generator to form fuel-rich gas, the fuel-rich gas enters an expansion section of the channel of the isolation section through a main fuel injector, and is fully mixed with fresh air and then is injected into an annular cavity of the rotary detonation combustor; the rotary detonation combustion chamber is provided with an ignition device, and a tail nozzle is arranged at an outlet of the rotary detonation combustion chamber to convert chemical energy into kinetic energy and generate thrust. The invention has higher combustion efficiency and working performance.

Description

Solid rocket ramjet based on detonation combustion

Technical Field

The invention belongs to the technical field of aerospace power, and particularly relates to a solid rocket ramjet engine based on detonation combustion.

Background

The chemical energy engine adopted in the current aerospace propulsion system has the internal combustion heat release process belonging to isobaric combustion. Through decades of development, power devices based on an isobaric combustion mode are improved day by day, the propulsion efficiency of the power devices is difficult to improve greatly, and a novel power propulsion device which meets the requirements of high speed and high efficiency is urgently needed to be developed. Compared with isobaric combustion, detonation combustion has the advantages of high energy release rate, high thermodynamic cycle efficiency, self-pressurization, short reaction zone and the like, and is close to constant volume combustion, so that a power system based on detonation combustion has a large promotion space in the aspect of propulsion performance, and has a wide application prospect.

The rotary detonation engine is a novel power propulsion device based on detonation combustion, can realize continuous rotary detonation only by one-time ignition, has the advantages of simple structure, high working frequency, self-pressurization, stable thrust and the like, can stably work under the condition of wide incoming flow speed, and can effectively work under a rocket mode and a stamping mode. In recent years, scientists in various countries have conducted research work on direct connection type experiments and free jet experiments of rotary detonation ramjet engines. Driscoll et al investigated the effect of geometry of an air breathing rotary detonation engine on engine operating mode and operating range. ([ 1] Driscoll R, anand V, george A S, et al. Investment on RDE operation by geometrical variation of the compressor and non-zle exit area C. In:9 U.S. national compressor meeting, cincinnati, ohio,2015 1-10.) Frolov et al performed wind tunnel experiments on rotary detonation engines under conditions of different incoming air flow Mach numbers and total temperatures, different equivalence ratios, and obtained thrust and specific impulse. The above-described test study further confirmed the feasibility of impact rotary detonation (Frolov S M, zvegintsev V I, ivanov V S, et al. Hydrogen-full deactivation ramjet model: wind tunnel tests at advanced air stream machine number 5.7and registration temperature 1500K J. International Journal of Hydrogen Energy,2018,43 (15): 7515-7524).

For a traditional solid rocket ramjet, the combustion mode in the afterburning chamber of the ramjet is isobaric combustion, so that the space for further improving the propelling performance is limited. In addition, as the detonation combustion is supersonic combustion, the propagation speed of the detonation wave is in the order of kilometers per second, and the requirement on the mixing efficiency of reactants is high. Therefore, research on the rotary knocking engine is currently mostly limited to gaseous fuel, but the gaseous fuel has problems of low density and inconvenience in carrying. The direct use of solid fuel and the efficient mixing of the solid fuel and air are key problems that limit the detonation and the stable operation of the rotary detonation engine and are problems to be solved urgently.

Disclosure of Invention

The invention aims to provide a solid rocket ramjet based on detonation combustion, which replaces an isobaric combustion mode in a afterburning chamber of the traditional solid rocket ramjet with a detonation combustion mode similar to isovolumetric combustion so as to improve the combustion efficiency and the working performance of the solid rocket ramjet. Meanwhile, the gas generator is used for pre-burning and gasifying the solid fuel so as to solve the problem of low mixing efficiency of the solid fuel and air.

The technical solution for realizing the purpose of the invention is as follows:

a solid rocket ramjet based on detonation combustion comprises a cylindrical outer barrel and an inner core body, wherein the outer barrel extends continuously along the axial direction, the inner core body is arranged along the length direction of the outer barrel, and an annular passage formed between the inner wall of the outer barrel and the outer wall of the inner core body forms an air inlet passage, an isolation section passage and a detonation combustion passage;

the outer cylinder body and the inner core body extend along the axial direction and form an annular channel for air flow and rich fuel gas to flow, mix and detonate;

the air inlet channel, the isolation section channel and the detonation combustion channel are sequentially arranged along the axial direction and are continuously communicated;

the expansion section of the isolation section channel is connected with the main fuel injection channel;

the inner core body is internally provided with a fuel gas generator, the shell of the fuel gas generator is of an empty cylindrical structure, and oxygen-poor propellant filled in the fuel gas generator completes combustion in the shell of the fuel gas generator and forms fuel-rich gas;

the outlet of the gas generator is connected with a steady flow ring cavity, and the diameter of the cross section of the steady flow ring cavity is larger than that of the outlet of the gas generator;

the rear end of the flow stabilizing ring cavity is connected with a main fuel injector, and the fuel-rich gas passes through the flow stabilizing ring cavity and is injected into the expansion section of the isolation section channel through the main fuel injector and is mixed with air flow;

the rotary detonation combustor is connected with the expansion section of the isolation section channel, and the fuel-rich gas is mixed with the air flow and then injected into the rotary detonation combustor;

an ignition device is arranged on the outer wall surface of the rotary detonation combustion chamber and is arranged near the head of the rotary detonation combustion chamber;

and an outlet of the rotary detonation combustion chamber is connected with a tail nozzle, and detonation products flow through the tail nozzle and are discharged out of the engine after being expanded.

Compared with the prior art, the invention has the following remarkable advantages:

the invention relates to a solid rocket ramjet based on detonation combustion, which is mainly divided into a primary isobaric combustion process of an oxygen-poor solid propellant in a gas generator and a secondary detonation combustion process in a rotary detonation combustion chamber, wherein the oxygen-poor solid propellant generates rich combustion gas through primary isobaric combustion, the rich combustion gas is sprayed into an expansion section of a channel of an isolation section through a main fuel injector arranged on the outer wall surface of an inner core body, and is fully mixed with fresh air captured by an air inlet channel and subjected to speed reduction and pressure boost through the isolation section, then the fresh air is sprayed into the rotary detonation combustion chamber, and the fresh air is expanded and discharged through a tail nozzle after undergoing the rotary detonation combustion process to generate thrust. Because the thermal cycle efficiency of detonation combustion is high, the detonation combustion is self-supercharging and the reaction area is short, the rotary detonation combustion chamber is used for replacing an isobaric combustion afterburning chamber of the traditional solid rocket ramjet engine, the working efficiency and the propelling performance of the engine can be effectively improved, the structure of the engine is simplified, the length of the afterburning chamber is shortened, the thrust-weight ratio of the engine is improved, and the engineering development of a novel power propelling system and a combined engine based on detonation combustion is promoted.

Drawings

Fig. 1 is a front sectional view of a solid rocket ramjet engine based on detonation combustion of an embodiment.

FIG. 2 is an enlarged partial cross-sectional view of an embodiment of a solid rocket ramjet engine main fuel injector based on detonation combustion.

10-an inner core body; 101-core body front part; 102-a rear core body; 103-main fuel injectors; 20-outer cylinder; 30-a gas generator; 301-a gasifier shell; 302-an oxygen-depleted solid propellant; 40-an ignition device; 50-a rotary detonation combustor; 60-tail nozzle; 90-a flow stabilizing ring cavity; 110-a second insufflating system; 70-an air inlet channel; 80-isolating the segment channel; 100-a detonation combustion channel; 11-a flow of air; 22-a fuel-rich gas stream; 33-detonation product stream;

Detailed Description

The invention is further described with reference to the following figures and embodiments.

Referring to fig. 1, the invention provides a solid rocket ramjet engine based on detonation combustion, which is used for the engineering development of a novel power propulsion system and a combined engine. A solid rocket ramjet based on detonation combustion comprising: the device comprises an outer cylinder body 20 which is cylindrical and continuously extends along the axial direction, an inner core body 10 which is arranged along the length direction of the outer cylinder body 20, an annular channel which is formed between the inner wall of the outer cylinder body 20 and the outer wall of the inner core body 10 forms an air inlet channel 70 for capturing fresh air, an isolation section channel 80 for decelerating and pressurizing and a detonation combustion channel 100 for chemical reaction of fuel and oxidant, and the expansion section of the isolation section channel 80 is connected with a main fuel injector 103. The gas generator 30 is arranged in the inner core body 10, the shell 301 of the gas generator 30 is in an empty cylinder structure, the inner part of the shell is filled with the oxygen-poor solid propellant 302, an ignition device (not shown in the figure) of the gas generator 30 ignites at a head position, and the oxygen-poor solid propellant 302 combusts isobarically in the gas generator 30 and forms the high-temperature and high-pressure rich gas 22 rapidly. The outlet of the gas generator 30 is connected with the flow stabilizing ring cavity 90, the main fuel injector 103 is arranged on the outer wall surface of the inner core body 10, and the fuel-rich gas 22 is rectified by the flow stabilizing ring cavity 90, is injected into the expansion section of the isolation section channel 80 through the main fuel injector 103 and is mixed with the fresh air flow 11. The rotary detonation combustor 50 is connected with the expanding section of the isolating section channel 80, and the rich fuel gas 22 is fully mixed with the fresh air flow 11 and then is injected into the rotary detonation combustor 50. The ignition device 40 is arranged on the outer wall surface of the rotary detonation combustion chamber 50 and is installed near the head of the rotary detonation combustion chamber 50, the outlet of the rotary detonation combustion chamber 50 is connected with the tail nozzle 60, after the rich fuel gas 22 and the fresh air flow 11 are subjected to continuous detonation combustion, the detonation product flow 33 is expanded through the tail nozzle 60 and then is discharged out of the engine.

The solid rocket ramjet based on detonation combustion is characterized in that incoming air 11 is captured by an air inlet 70, then the incoming air 11 is subjected to speed reduction and pressure boosting through an isolation section channel 80, and is mixed with rich fuel gas 22 in an expansion section of the isolation section channel 80 and then is sprayed into a rotary detonation combustor 50 together.

The isolation section passage 80 of the embodiment shown in fig. 1 sequentially comprises an equal straight section, a convergent section and an expansion section from front to back in the flow direction, incoming air 11 captured by the air inlet duct 70 is subjected to speed reduction and pressure boost through the isolation section, and then is subjected to secondary speed reduction and pressure boost through a structure of first convergence and then expansion, so that the incoming flow speed is further reduced, and the mixing efficiency of the rich fuel gas 22 and the fresh air 11 is improved. However, the present invention is not limited to the structure of the isolation section passage 80, and other flow passage structures, such as tapering, converging before diverging, etc., can be implemented.

The gas generator 30 is disposed in a cavity in the front core 101 and is comprised of a gas generator housing 301 and an oxygen-depleted solid propellant 302. The gas generator 30 in this embodiment is in a hollow cylindrical structure, and the propellant is an oxygen-poor solid propellant, but the gas generator 30 and the propellant 302 in the present invention are not limited to the structure and kind shown in this embodiment, and the propellant is not limited to solid matter, and can be a liquid or gaseous propellant, but the proportions of the fuel and the oxidizer in the propellant are rich and lean in oxygen.

The oxygen-poor solid propellant in the gas generator 30 in the embodiment is subjected to isobaric combustion to generate high-temperature and high-pressure rich fuel gas 22, the gas generator 30 is connected with a steady flow ring cavity 90, the diameter of the ring cavity is larger than the diameter of an outlet of the gas generator, the rich fuel gas flows through the steady flow ring cavity 90 from the gas generator, is rectified by the steady flow ring cavity 90, is sprayed into an expansion section of the isolation section channel through a main fuel injector 103, is mixed with fresh air, and then enters a combustion chamber. The main fuel injectors in the embodiment of the present invention shown in fig. 1 are circumferentially distributed small holes, and the diameter, the distance between the holes, the number of the small holes, and the injection angle of the small holes all affect the mixing state of the reactants entering the rotary detonation combustor 50. Wherein, the diameter and the quantity of the small holes are designed according to the incoming flow mass flow rate, the fuel-rich gas component and the reaction equivalence ratio variation range. The hole spacing is influenced by the circumferential size of the engine and the number of the small holes, and in order to ensure the mixing efficiency of the rich fuel gas 22 and the incoming flow air 11, the ratio of the hole spacing to the diameter of the small holes is less than or equal to 10. The fuel hole injection angle, namely the included angle between the injection direction of the fuel-rich gas 22 and the direction of the incoming air 11, is 30-90 degrees. The orifice configuration and injection angle in the example shown in fig. 2 is 60 deg.. In particular, the main fuel injector structure of the present invention is not limited to the structure shown in fig. 2.

The design of the flow stabilizer ring cavity 90 is related to the outlet geometric parameters of the gas generator 30, and is generally designed according to the outlet area of the gas generator 30, if the sectional area of the flow stabilizer ring cavity 90 is too small, the rectification effect is poor, and the axial speed of the gas generator 30 is too large, which is not favorable for the injection of the fuel-rich gas 22; if the sectional area of the annular cavity is too large, the volume of the annular cavity is too large, the pressure drop of the fuel-rich gas 22 is too large, the effective injection and penetration depth of the gas are affected, and the mixing effect of the gas is further affected.

The rotary knocking combustor 50 is connected to the expanding section of the isolating section passage 80, and is an annular combustion passage composed of the inner wall surface of the outer cylinder 20 and the outer wall surface of the core body rear portion 102. The configuration of the rotary knocking combustor 50 shown in the present embodiment is a circular ring structure. The ignition device 40 is arranged on the outer wall surface of the rotary detonation combustion chamber 50, the ignition device 40 is arranged near the head of the rotary detonation combustion chamber 50 in the embodiment, the outlet of the combustion chamber is connected with the tail nozzle 60, the detonation product flow 33 expands through the tail nozzle 60, the heat energy is converted into kinetic energy and then is discharged out of the engine, and thrust is generated.

The gas generator 30 of the embodiment shown in fig. 1 is a solid rocket engine, but the gas generator 30 of the present invention is not limited to the structure of the embodiment shown, and other types or structures of fuel gas generators, such as liquid rocket engines, etc., may be implemented in combination with the rotary detonation combustor 50.

The rotary detonation combustor 50 of the embodiment shown in fig. 1 is in a circular ring structure, and the flow channel profile is in an equal straight shape, but the rotary detonation combustor 50 in the present invention is not limited to the structure shown in the embodiment, the rotary detonation combustor 50 may be in a cylindrical shape without an inner cylinder, a disc shape, and other combustor structures, and the flow channel profile may be in a divergent shape, a convergent shape, and any other profile.

The configuration and exit area of the aft nozzle 60 of the rotary detonation combustor 50, which may be a laval nozzle (as shown in fig. 1), a convergent nozzle, or a divergent nozzle, also affects the operating characteristics of the engine. The inner and outer wall surfaces of the detonation combustion channel 100 of the equal straight type rotary detonation combustor 50 are parallel, and the channel cross-sectional area is constant along the axial direction. In the divergent rotary detonation combustor 50, the outer wall of the detonation combustion channel 100 expands towards the inside of the outer cylinder 20, the inner wall expands towards the inside of the inner core body rear part 102, and the cross-sectional area of the channel gradually increases along the axial direction. In the tapered rotary detonation combustor 50, the inner and outer wall surfaces of the detonation combustion channel 100 simultaneously expand into the detonation combustion channel 100, and the cross-sectional area of the channel gradually decreases along the axial direction.

The installation position of the ignition device 40 for initiating the rotary detonation combustor 50 and the ignition energy both affect the establishment process of the detonation wave in the rotary detonation combustor 50, the ignition device 40 in the embodiment shown in fig. 1 is installed near the head of the rotary detonation combustor 50, but not limited to this position, the installation position can be arranged along the axial position of the rotary detonation combustor 50, the installation direction can be vertical to the wall surface of the outer cylinder 20 or tangential to the outer wall surface of the outer cylinder 20, and the ignition device can be flush-mounted, and projection-type installation modes. The requirement for the discharge energy of the ignition device is determined according to the components of the fuel-rich gas, and the ignition devices such as a high-energy spark plug, a pre-detonation pipe, a thermal jet pipe and the like can be selected.

As shown in fig. 1, a second injection system 110, consisting of an annular cavity and injectors, is provided within the inner core back 102, the second injection system 110 communicating with the detonation combustion channel 100 and injecting fuel into the rotating detonation combustor 50. When the main fuel injector 103 alone is insufficient to generate the spin detonation wave, or when the fuel is packed in a split-type manner to improve combustion efficiency, the fuel may be injected into the spin detonation combustor 50 through the second injection system 110, but the flow rate of the fuel injected through the second injection system 110 is generally no more than 20% of the total flow rate of the fuel.

The solid rocket ramjet based on detonation combustion uses the rotary detonation combustion chamber to replace an isobaric combustion afterburning chamber of the traditional solid rocket ramjet, can effectively improve the working efficiency and the propulsion performance of the engine, simplifies the structure of the engine, shortens the length of the afterburning chamber, improves the thrust-weight ratio of the engine, and promotes the engineering development of a novel power propulsion system and a combined engine based on detonation combustion.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents or improvements made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims

1. A solid rocket ramjet based on detonation combustion is characterized by comprising an outer cylinder (20) which is cylindrical and continuously extends along the axial direction, and an inner core (10) which is arranged along the length direction of the outer cylinder (20), wherein an air inlet (70), an isolation section channel (80) and a detonation combustion channel (100) are formed by an annular channel formed between the inner wall of the outer cylinder (20) and the outer wall of the inner core (10);

the outer cylinder (20) and the inner core body (10) extend along the axial direction, and the outer cylinder and the inner core body are separated to form an annular channel for flowing, mixing and knocking combustion of the air flow (11) and the rich combustion gas (22);

the air inlet channel (70), the isolation section channel (80) and the detonation combustion channel (100) are sequentially arranged along the axial direction and are communicated with each other continuously;

the expanding section of the isolating section channel (80) is connected with a main fuel injection channel;

the internal core body (10) is divided into two parts, the front part (101) of the internal core body and the external cylinder body (20) form an air inlet channel (70) and an isolation section channel (80), and the rear part (102) of the internal core body and the external cylinder body (20) form a detonation combustion channel (100);

a gas generator (30) is arranged in the inner core body (10), a shell (301) of the gas generator (30) is of a hollow cylindrical structure, oxygen-poor propellants (302) filled in the shell of the gas generator complete primary isobaric combustion in the shell (301) of the gas generator, and high-temperature and high-pressure rich fuel gas (22) is formed; the fuel-rich gas (22) is mixed with the air flow (11) to enter the detonation combustion channel (100) for improving the detonation success rate and detonation combustion efficiency of the fuel;

a second injection system (110) is arranged in the rear part (102) of the inner core body, and the second injection system (110) is communicated with the detonation combustion channel (100) through injection small holes distributed circumferentially so as to inject fuel into the detonation combustion channel (100) for the second time, so that the combustion efficiency is further improved;

the outlet of the gas generator (30) is connected with a flow stabilizing ring cavity (90), and the diameter of the section of the flow stabilizing ring cavity (90) is larger than that of the outlet of the gas generator (30);

the rear end of the flow stabilizing ring cavity (90) is connected with a main fuel injector (103), and the fuel-rich gas (22) passes through the flow stabilizing ring cavity (90) and is injected into the expansion section of the isolating section channel (80) through the main fuel injector (103) and is mixed with the air flow (11);

the rotary detonation combustor (50) is connected with the expanding section of the isolating section channel (80), and the fuel-rich gas (22) is mixed with the air flow (11) and then is injected into the rotary detonation combustor (50);

an ignition device (40) is arranged on the outer wall surface of the rotary detonation combustion chamber (50), and the ignition device (40) is installed near the head of the rotary detonation combustion chamber (50);

the outlet of the rotary detonation combustor (50) is connected with a tail pipe (60), and a detonation product flow (33) is expanded through the tail pipe (60) and then is discharged out of the engine.

2. The detonation combustion-based solid rocket ramjet engine according to claim 1, characterized in that said flow stabilizer ring cavity (90) exit plane divides said inner core (10), said flow stabilizer ring cavity (90) being preceded by said inner core front portion (101) and said flow stabilizer ring cavity (90) being followed by said inner core rear portion (102).

3. The detonation combustion-based solid rocket ramjet engine according to claim 1, characterized in that the igniter of said gas generator (30) is located at the head position of the core (10).

4. The detonation combustion-based solid-rocket ramjet engine according to claim 1, characterized in that the configuration of the rotary detonation combustion chamber (50) is of the iso-straight type, of the divergent type or of the convergent type.

5. The detonation combustion-based solid rocket ramjet engine according to claim 1, characterized in that said rotary detonation combustion chamber (50) is of a straight configuration with parallel inner and outer wall surfaces of the detonation combustion channel (100) and a channel cross-sectional area that is axially constant.

6. The detonation combustion-based solid rocket ramjet engine according to claim 1, characterized in that said rotary detonation combustion chamber (50) is of a divergent configuration, the outer wall of said detonation combustion channel (100) expanding inwardly towards said outer cylinder (20), the inner wall expanding inwardly towards said inner core rear portion (102), the channel cross-sectional area increasing progressively in the axial direction.

7. The detonation combustion-based solid rocket ramjet engine according to claim 1, characterized in that said rotary detonation combustion chamber (50) is tapered in configuration, the inner and outer wall surfaces of said detonation combustion channel (100) expand simultaneously into said detonation combustion channel (100), and the channel cross-sectional area decreases gradually in the axial direction.