METHOD FOR CONTROLLING FLOW SEPARATION ON SUCTION SURFACE OF STATOR BLADE OF AXIAL COMPRESSOR/FAN BY MEANS OF MICRO AIR INJECTION

Abstract

A method for controlling flow separation on a suction surface of a stator blade of an axial compressor/fan by means of micro air injection is characterized in that a stator blade of the axial compressor/fan is hollow and is formed by several two-dimensional hollow blade profiles stacked spanwisely; the blade profile is slotted to form a slotted blade profile; an inlet of a slot is at leading edge of the blade profile and an outlet is on a suction surface; when an airflow flows through a blade, a small portion of the airflow flows into the slot and then is ejected via the outlet; and the inlet of the slot exactly faces the incoming flow. The method can be used for an axial compressor or an axial fan to reduce flow loss and improve its efficiency.

Claims

1. A method for controlling flow separation on a suction surface of a stator blade of an axial compressor/fan by means of micro air injection, wherein the stator blade of the axial compressor/fan is hollow and is formed by a plurality of two-dimensional hollow blade profiles stacked spanwisely; a blade profile is slotted to form a slotted blade profile; an inlet of a slot is at a leading edge of the blade profile and an outlet is on the suction surface; when an airflow flows through a blade, a portion of the airflow flows into the slot and then is ejected via the outlet; and the inlet of the slot exactly faces an incoming flow.

2. The method according to claim 1, wherein the outlet of the slot, located on the suction surface of the blade profile, is located on the suction surface where a boundary layer needs to be blown off.

3. The method according to claim 1, wherein a shape of the slot in the blade profile is initially determined artificially; a flow field of a cascade formed by slotted blade profiles is calculated by numerical simulation; the shape of the slot in the blade profile is modified according to analysis on structure of the flow field, wherein a width δ of the slot is increased to increase a flow rate in the slot, a distance L between the outlet of the slot and the leading edge of the blade profile is reduced to control a boundary layer on the suction surface earlier; and finally, an optimized slot in the blade profile is obtained to achieve an aerodynamic performance of the blade profile and low flow loss in the slot.

4. The method according to claim 1, wherein the method is used for controlling flow separation on a suction surface of a rotor blade of the axial compressor/fan.

5. The method according to claim 2, wherein the method is used for controlling flow separation on a suction surface of a rotor blade of the axial compressor/fan.

6. The method according to claim 3, wherein the method is used for controlling flow separation on a suction surface of a rotor blade of the axial compressor/fan.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is a slotted blade profile of a stator;

[0013] FIG. 2 is a partial enlarged view of a front portion of the slotted blade profile;

[0014] FIG. 3 shows a slotted blade profile in the embodiment;

[0015] FIGS. 4A and 4B show flow lines and contours of Mach numbers of flow fields of two cascades formed by a slotted blade profile and an unslotted blade profile in the embodiment; and

[0016] FIG. 5 is the flow loss and flow turning angle with attack angle of the two cascades in the embodiment.

[0017] In the figures, 1. leading edge of a blade profile, 2. a small portion of airflow, 3. slot in the blade profile, 4. blade profile, 5. suction surface of the blade profile, 6. pressure surface of the blade profile, 7. chord of the blade profile, 8. rear edge of the blade profile.

DETAILED DESCRIPTION

[0018] The present disclosure is further described below with reference to the accompanying figures and embodiments.

[0019] Implementation

[0020] A method of the present disclosure for controlling a boundary layer on a suction surface of a stator of an axial compressor/fan (i.e., a fan of a compressor) by means of micro air injection generated by velocity impulse is described below with reference to FIG. 1.

[0021] Generally, a number of blade profiles are stacked in the radial direction according to a certain stacking rule, and the profiles are used as the skeleton and spline curved surfaces are used to cover the skeleton to form an axial compressor/fan stator blade. Therefore, the blade profiles are basic elements of the blade, and aerodynamic performance of the blade is determined by the blade profiles. The stator blade in the present disclosure is hollow and is formed by slotted blade profiles. A slot (3) in each blade profile (4) has one end (inlet) at a leading edge (1) of the blade profile and the other end (outlet) at a position where a boundary layer on the suction surface (5) of the blade profile is required to be blown off. When airflows flow through the blade, a small portion of the airflows (2) flow into the slot (3) and then are ejected via the outlet. The jet flow increases momentum on the boundary layer at this position, suppresses growth of the boundary layer, and controls flow separation on the boundary layer. In this way, flow loss of the stator is reduced, and efficiency of the axial compressor/fan is improved. Because an inlet of the slot exactly faces incoming flows, the small portion of the airflows in the slot has high momentum, so that a jet flow from the outlet of the slot has a high velocity. Based on this, the boundary layer on the suction surface can be effectively suppressed.

[0022] The blade profile mainly has the following aerodynamic performance indexes: under a certain inlet Mach number and inlet angle, a given airflow turning angle is reached and the flow loss is as small as possible, and attack angle range of the low loss is as large as possible. the shape of the slot is initially determined artificially; the flow field of the cascade formed by the slotted blade profiles is calculated by means of numerical simulation; the shape of the slot in the blade profile is modified according to analysis on structure of the flow field. For example, a width δ of the slot is increased to increase the flow rate in the slot; a distance L between the outlet of the slot and the leading edge of the blade profile is reduced to control the boundary layer on the suction surface earlier. Finally, an optimized slot in the blade profile is obtained to achieve excellent aerodynamic performance of the blade profile and low flow loss in the slot.

Embodiment

[0023] FIG. 3 shows a blade profile of a stator of an axial compressor, slotted to achieve micro air injection on the suction surface. Table 1 shows main performance parameters of the cascade. The width of the inlet of the slot in the blade profile accounts for 1% of the chord length, and the width of the outlet of the slot in the blade profile accounts for 0.5% of the chord length. FIGS. 4A and 4B show comparison of the simulated flow fields of the two cascades formed by the slotted blade profiles (FIG. 4B) and unslotted blade profiles (FIG. 4A) at a large positive attack angle. As shown in FIGS. 4A and 4B, flow separation on a suction surface of the slotted blade profile can be suppressed effectively. FIG. 5 shows comparison of flow loss ω and flow turning angles Δβ of the two cascades. As shown in FIG. 5, at a positive attack angle, the slotting can significantly reduce the flow loss and increase the flow turning angle. The greater the attack angle, the greater the degree of improvement. The technical solution of this application can effectively inhibit the flow separation of the suction surface and reduce the flow loss. Therefore, this patent can be widely used in engineering practice.

TABLE-US-00001 TABLE 1 Main parameters of the cascade Inlet Mach Cascade Flow number Density Inlet angle (°) turning angle (°) Loading factor 0.7 1.5 42 36 0.45

[0024] The above descriptions are merely preferred implementations of the present disclosure. It should be noted that a person of ordinary skill in the art may further make several improvements and modifications without departing from the principle of the present disclosure, and such improvements and modifications shall also be deemed as falling within the protection scope of the present disclosure.