CN113431637A - Pure radial type supersonic speed micro turbine structure with air bearing - Google Patents

Abstract

The invention relates to a pure radial type supersonic speed micro turbine structure with an air bearing, which comprises the following components in part by weight: the gas flow enters a turbine stator flow passage (5) from the radial direction, and then the flow direction in the turbine is kept radial all the time; the stator part comprises a stator blade (2), an upper casing (1) and a lower casing (4) to form a scaling flow channel, and the sectional area of the throat part of the flow channel is equal to the critical area of the designed flow, so that the air flow is accelerated to supersonic speed; the inlet blade of the rotor impeller (3) is in a blunt shape to block part of the flow area so as to adapt to the small flow design requirement of the micro turbine; dynamic pressure grooves (7) are formed in the back face and the edge of the rotor impeller (3) and are matched with the lower casing (4) to form a dynamic pressure air bearing flow channel (6), and when the rotating speed of the turbine reaches a design value, gas in the dynamic pressure grooves provides supporting force due to viscosity, so that the thrust and radial bearing effects are achieved. The invention can realize the expansion work of small-flow high-pressure gas, and has the characteristics of compact structure, extremely high rotating speed, small required flow, capability of using cold air to do work, high expansion ratio and strong work-doing capacity.

Description

Pure radial type supersonic speed micro turbine structure with air bearing

Technical Field

The invention belongs to the field of rotor power mechanical structure design, and relates to a pure radial type supersonic speed micro turbine structure with an air bearing.

Background

The development of rotor power machinery has reached a high technical level, and large-scale gas turbines and steam turbines provide continuous high-power in various fields such as energy, ships, aerospace and the like. On the other hand, the miniaturization of the turbine is always a difficult problem, and the efficiency of the turbine under the condition of small flow and low temperature is far lower than that of the turbine under the ordinary working condition, so that the turbine is frequently powered by solar energy, storage batteries and even piston type heat engines under the low-power application scenes of distributed energy, single-soldier carrying equipment, space satellite functions and the like.

With the development of technology, the power density requirements for low-power application scenarios are also gradually increasing. However, the development of solar energy and storage batteries requires research progress of basic materials science, and the piston type heat engine is close to the theoretical upper limit of efficiency and is difficult to continue to develop. It has become a viable solution to develop a microturbine suitable for low flow, low power applications.

At present, the method of reducing the power drop while miniaturizing the turbine is to increase the expansion ratio. However, the increase of the expansion ratio beyond a certain limit may cause various problems such as supersonic airflow, ultrahigh rotation speed, complex flow field structure, etc., and these problems are difficult to solve in the conventional turbine design.

Therefore, a new turbine structure is proposed to solve or alleviate the above problems, and to achieve further development of power density of small-energy power, which has important practical value.

The invention provides a pure radial type supersonic speed micro turbine structure with an air bearing, which can realize expansion work of small-flow high-pressure gas, and has the characteristics of compact structure, extremely high rotating speed, small required flow, capability of using cold air to do work, high expansion ratio and strong work-doing capacity.

Disclosure of Invention

Technical problem to be solved

The invention provides a pure radial type supersonic speed micro turbine structure with an air bearing, which solves the problems of supersonic speed airflow, ultrahigh rotating speed and complicated flow field structure of the existing small-flow turbine machinery under the high expansion ratio design.

(II) technical scheme

In order to solve the above technical problem, an embodiment of the present invention provides a pure radial supersonic microturbine structure with an air bearing, including:

the air compressor comprises an upper casing 1 and a lower casing 4, wherein a stator blade 2 and a rotor impeller 3 are clamped between the two casings, the rotor impeller 3 rotates around a rotating shaft R, every two pieces of the stator blade 2 are matched with the upper casing and the lower casing to form a stator airflow channel 5, and the rotor impeller is matched with the lower casing to form a dynamic pressure air bearing channel 6.

In one embodiment, the stator blade 2 is tightly connected to the upper casing 1 and the lower casing 4 without a tip clearance.

In one embodiment, the stator blades 2 are plural in number and are arranged equidistantly in the circumferential direction of the casing.

In one embodiment, every two blades between the stator blades 2 are in a group, and a stator airflow channel 5 generated by matching one group of stator blades with the upper casing 1 and the lower casing 4 has a change rule that the cross-sectional area of the channel is firstly contracted and then expanded.

In one embodiment, the narrowest cross-sectional area A of the stator flow channel 5_crComprises the following steps:

where G is the design point mass flow, ρ_crCritical density of gas at design point, c_crAnd n is the number of the stator blades for the design point gas critical sound velocity.

In one embodiment, the shape of the blades at the inlet of the rotor wheel 3 is blunt and the blade area occupies more than 50% of the inlet area.

In one embodiment, the blades of the rotor wheel 3 are flush in the blade height direction and do not change with radial position changes.

In one embodiment, the disk of the rotor wheel 3 is engraved with dynamic pressure grooves 7, including radial dynamic pressure grooves 71 and thrust dynamic pressure grooves 72, at the rim and back of the disk.

In one embodiment, the rotor wheel 3 is supported by the hydrodynamic air bearing flow passages 6 without any direct or indirect mechanical connection or contact between the upper casing 1, the lower casing 4 and the stator blades 2.

In one embodiment, the hydrodynamic bearing flow passages 6 include radial bearing flow passages 61 and thrust bearing flow passages 62.

(III) advantageous effects

The invention provides a pure radial type supersonic speed micro turbine structure with an air bearing, which has the following advantages: 1. the blades are used for forming the convergent-divergent flow channel, so that the supersonic speed airflow can be provided, and meanwhile, the partial air inlet problem caused by the use of the convergent-divergent straight nozzle in the traditional method is avoided; 2. the dynamic pressure groove is etched on the rotor impeller wheel disc and is matched with the casing to form a dynamic pressure air bearing structure, so that the problem of a mechanical bearing without adaptation at ultrahigh rotating speed is solved; 3. compared with the variable-vane-height radial rotating axial design of the conventional centripetal turbine, the variable-vane-height radial design has the advantages that the internal flow field is changed from three dimensions to quasi two dimensions, and the design and analysis difficulty is greatly reduced.

Drawings

FIG. 1 is a schematic cross-sectional view of a pure radial supersonic micro-turbine structure with an air bearing of the present invention;

FIG. 2 is a schematic top view of a pure radial supersonic micro-turbine structure with an air bearing (without an upper casing) according to the present invention;

FIG. 3 is a schematic view of a rotor disk radial dynamic pressure groove of a pure radial supersonic speed micro-turbine structure with an air bearing of the present invention;

FIG. 4 is a schematic view of a thrust dynamic pressure groove of a rotor disk of a pure radial supersonic speed micro turbine structure with an air bearing of the invention.

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

As shown in fig. 1, the structure includes:

the air compressor comprises an upper casing 1 and a lower casing 4, wherein a stator blade 2 and a rotor impeller 3 are clamped between the two casings, the rotor impeller 3 rotates around a rotating shaft R, every two pieces of the stator blade 2 are matched with the upper casing and the lower casing to form a stator airflow channel 5, and the rotor impeller is matched with the lower casing to form a dynamic pressure air bearing channel 6.

The dynamic pressure gas bearing flow passage 6 includes a radial dynamic pressure gas bearing flow passage 61 and a thrust dynamic pressure gas bearing flow passage 62. The rim and the back of the rotor wheel 3 are engraved with dynamic pressure grooves 7 including radial dynamic pressure grooves 71 and thrust dynamic pressure grooves 72.

When the turbine works, working medium gas uniformly flows into the stator airflow channel 5 from the circumferential direction, then flows into the rotor impeller 3, and finally is discharged from the gas outlet of the upper casing 1. In the whole working process, gas flows along the radial direction, the gas is discharged axially after the working is finished, and the height of the blade is not changed, so that the flow field is quasi-two-dimensional.

Further, the purely radial design may allow for a tight connection between the stator blades 5 and the upper and lower casings 1, 4 without tip clearance leakage flow.

Furthermore, the blades are used as supersonic stator flow passages to replace common Laval nozzles, so that full circumferential air intake can be realized, and the unsteady effect caused by partial air intake of the nozzles is avoided.

The complexity of flow field design is greatly reduced, and a foundation is laid for using supersonic airflow next time.

As shown in fig. 2, every two blades between every two stator blades 2 are in a group, and a stator airflow channel 5 is generated by the cooperation of one group of stator blades with the upper casing 1 and the lower casing 4, and the sectional area of the channel is changed by first contracting and then expanding.

In one embodiment, the narrowest cross-sectional area A of the stator flow channel 5_crComprises the following steps:

where G is the design point mass flow, ρ, for this example_crCritical density of gas at design point, c_crAnd n is the number of the stator blades for the design point gas critical sound velocity.

In one embodiment, the smallest cross-sectional area of the stator flowpath is located proximate the outlet. However, the position of the minimum cross-sectional area may be adjusted according to specific situations, and different exit airflow mach numbers may be obtained by adjusting the position, which is not limited in the embodiment of the present invention.

By the design, supersonic air flow can be obtained on the premise of not adopting partial air inlet.

As shown in fig. 3, the disk of the rotor wheel 3 is engraved with radial dynamic pressure grooves 71 at the disk edge.

As shown in fig. 4, the disk of the rotor wheel 3 is engraved with thrust dynamic pressure grooves 72 on the back surface of the disk.

In one embodiment, the radial dynamic pressure grooves take a herringbone groove shape, and the thrust dynamic pressure grooves take a spiral groove shape. However, the shape, number, and size of the dynamic pressure grooves may be adjusted according to specific situations, and different bearing capacities and stabilities may be obtained by different adjustments, which is not limited in the embodiments of the present invention.

The rotating speed of the turbine adopting the dynamic pressure air bearing can reach more than one million revolutions per minute, which far exceeds the upper limit of the allowable rotating speed of the existing mechanical bearing, and the micro-engine is easier to realize than the mechanical bearing. The dynamic pressure air bearing is directly etched on the turbine, so that the upper limit of the rotating speed of the turbine can be improved on the premise of compactness.

In conclusion, the invention adopts the stator blades with the convergent-divergent flow channels to realize supersonic airflow under the condition of full circumferential air inlet, adopts the self-provided air bearing to realize ultrahigh rotating speed under the compact condition, adopts the pure radial design to relieve the problem of complicated flow field structure, and realizes the miniaturization of the turbine by solving the three problems.

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, improvements and the like that are within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. The invention relates to a pure radial type supersonic speed micro turbine structure with an air bearing, which is characterized by comprising the following components:

go up casket (1) and lower casket (4), accompany stator blade (2) and rotor impeller (3) between two casings, rotor impeller revolves rotation axis (R) and rotates, stator blade is every two with upper and lower casket cooperation formation stator air current runner (5), rotor blade forms dynamic pressure air supporting bearing runner (6) with lower casket cooperation.

2. The pure radial supersonic microturbine structure with self-contained aerostatic bearing according to claim 1, characterized by the fact that the stator blade (2) is tightly connected to the upper casing (1) and the lower casing (4) without tip clearance.

3. The pure radial supersonic microturbine structure with self-contained air bearing according to claim 2, characterized in that said stator blades (2) are plural in number and arranged equidistantly along the casing circumference.

4. The pure radial supersonic micro turbine structure with air bearing according to claim 3, wherein every two blades between the stator blades (2) are in one group, and the stator airflow channel (5) generated by the cooperation of one group of stator blades with the upper casing (1) and the lower casing (4) has a variation rule that the cross-sectional area of the channel is contracted and then expanded.

5. The pure radial supersonic microturbine structure with self-contained aerostatic bearing according to claim 4, characterized in that the narrowest cross-sectional area A of the stator airflow channel (5)_crComprises the following steps:

where G is the design point mass flow, ρ_crCritical density of gas at design point, c_crAnd n is the number of the stator blades for the design point gas critical sound velocity.

6. The pure radial supersonic microturbine structure with self-contained air bearing as claimed in claim 1, wherein the shape of the blade at the inlet of the rotor wheel (3) is blunt and the blade area occupies more than 50% of the inlet area.

7. The pure radial supersonic microturbine structure with self-contained air bearing according to claim 6, characterized in that the blades of said rotor wheel (3) are flush in the blade height direction and do not change with the change of radial position.

8. The pure radial supersonic microturbine structure with self-bearing air bearing according to claim 7, wherein the wheel disk of said rotor wheel (3) is engraved with dynamic pressure grooves (7) at the edge and back of the wheel disk, including radial dynamic pressure grooves (71) and anti-thrust dynamic pressure grooves (72).

9. The pure radial supersonic microturbine structure with self-contained aerostatic bearings according to claim 8, characterized by the fact that the rotor wheel (3) is supported by the hydrodynamic aerostatic bearing flow channels (6) without any direct or indirect mechanical connection or contact between the upper casing (1), the lower casing (4) and the stator blades (2).

10. The pure radial supersonic microturbine structure with self-contained air bearings as claimed in claim 9 wherein said hydrodynamic air bearing flow passages (6) comprise radial air bearing flow passages (61) and thrust air bearing flow passages (62).

Images