CS223352B1 - Axial ventilator of the reversible electric rotating machine - Google Patents

Abstract

The present invention relates to engine generators for pumping station and solves the cooling problem these machines. The axial fan is fixed to the hub rotating blades that are freely rotatable and whose extreme positions are defined by cues located between adjacent orbits paddles. At the outward edges of the orbits blades, on their part facing towards the hubs of the fan may be rotating blades fitted with protrusions or projections with rollers, adjacent blades touching each other. Circular blades can interconnected rods. Cylindrical pins on which they are rotating rotating blades can be formed either on the blades or on the hub the fan.

Description

The invention relates to generator-motors for pumping stations and solves the problem of cooling these machines.

The axial fan has impeller blades mounted on the hub, which are freely rotatable and whose extreme positions are defined by stops placed between adjacent impeller blades. At the leading edges of the impeller blades, at their portions facing the hub of the fan, the impeller blades may be provided with protrusions or followers with followers which the adjacent impellers contact with each other. The rotating vanes can be interconnected by connecting rods. Cylindrical pins on which the rotating blades are rotatable can be formed either on the rotating blades or on the fan hub.

The invention relates to an axial fan of a reversible electric rotary machine, the impeller of which is mounted on the rotor of the machine and whose impeller blades are connected to the hub by means of cylindrical pins with radially oriented axes.

In electric machines rotating with one sense of rotation, axial fans are preferably used, the impellers of which are mounted directly on the machine shaft. These axial fans move a cooling gas, such as air, hydrogen, etc., to remove heat loss from the active parts of the machine. As a rule, two fans are placed on the machine to draw cooling gas from the machine's outer casings and drive it into the machine. The advantage of axial fans is the relatively good efficiency and advantageous direction of the gas exiting the fan relative to the other ventilation tract of the machine. For reversible machines, axial fans have not yet been used. In fact, known axial fans change the direction of gas flow as the direction of rotation changes, which contradicts the requirements of the ventilation circuit. In addition, the aerodynamic efficiency of the impeller blade axial fan decreases sharply in the opposite direction of rotation.

Therefore, in reversible machines, for example generator motors for pumped storage units, ventilation was solved by means of radial fans, possibly in combination with the own ventilation effect of the rotor star, or by means of foreign fans. All of these arrangements have certain disadvantages over the use of axial fans on the shaft, either with increased ventilation losses or with a more complicated machine layout.

These disadvantages are overcome by the invention of an axial fan of a reversible electric machine, the principle of which is that the rotating blades of the fan are mounted freely rotatably on the hub of the fan, their extreme pivoting positions being defined by stops. The axis of symmetry of the drop profile of the fan blade has a common point with the radially oriented axis of rotation of the fan blade. The contact point of the two adjacent fan blades with the center of rotation of each of them forms an angle of less than 90 degrees.

At the leading edges of the fan blades there are projections in the extension of the blade profile on a portion of the radial height of the fan blades adjacent the fan hub to form a point of contact of two adjacent fan blades. On the leading edges of the fan blades or on the leading edge lugs, rollers are mounted whose axis of rotation is parallel to the axis of rotation of the fan blade. The connecting rods of all fan blades are rotatably attached to the fan impeller blades at their leading edges by means of pins. The stops defining the extreme positions of the pivoting movement of the fan blades are formed by protrusions between adjacent fan blades on the outer shell of the fan hub. Cylindrical pins with a radially oriented axis of rotation are formed on the rotating vanes of the fan and are rotatably mounted in the hub of the fan.

The fan hub is provided with cylindrical pins with a radially orientated axis of rotation on which the rotating blades of the fan are mounted. The extreme positions of the fan blades are asymmetrical to the axial beam passing through the radially oriented axis of rotation. The center portion of the spherical surface of the outer shell of the hub of the fan radius R _and is at the intersection of the pivot axis of the fan impeller blades and the fan axis. The center of the spherical surface of the inner surface of the fan throat with radius r _B is at the intersection of the axis of rotation of the fan impeller and the fan axis.

An exemplary embodiment of the present invention is shown in the drawings, wherein Fig. 1 shows a schematic cross-section of a dual-sense generator. Figures 2a and 2b show circulating blades 2 with stops 6 which define angles γ 1 and β 2. Figures 3a, 3b, 3c show fan blades 2 at their leading edges 10, they are protrusions 9, or are equipped with rollers 16, to form a stop at point 8 of contact of two adjacent fan blades 2. In Figs. 4a, 4b, connecting rods 11 are secured to the fan blades 2 by means of pins 12 ensuring simultaneous flipping of all fan blades 2.

FIG. 5 shows the pivotal mounting of the fan impeller 2, wherein the pin 13 is part of the fan impeller 2. FIG. 6 shows the fixation of the fan blade 2 by another solution. Fig. 7 shows a detail of a cross-section of a fan.

Fig. 1 is a schematic cross-sectional view of a generator for dual sense rotation. Two axial fans drive the cooling air from the outer casings inside the machine and the flow direction is indicated by arrows. The impeller of each of the fans comprises a fan hub 1 and a fan impeller 2. The standing part of the fan forms the fan neck 3. The fan blades 2 are freely rotatable about a radially oriented pivot axis 4.

Giant. 2a, 2b show in an exploded axial view the axial fan blades with the fan blades 2 in two extreme positions. The fully indicated position corresponds to the direction of rotation from left to right, the dashed position to the opposite direction of rotation. The developed section of the fan impeller 2 has a drop profile at each fan radius, symmetrical about its axis 18. The fan impeller 2 is mounted on the fan hub 1 pivotally about cylindrical pins 5 whose axis is radial. The end positions of the fan blades 2 are fixed for the respective direction of rotation by the stops 6, which are designed as radially low projections of the fan hub 1. The extreme positions of the fan blades 2 in Fig. 2b are asymmetrical to the axial beam 7 passing through the pivot axis, i.e. the angles between the blade profile axis 18 and the tangential beam 17 passing the radially oriented pivot axis 4 are not for the extreme positions of the fan blades 2 same (χι 4 = 72).

Giant. Figures 3a, 3b show in detail a view of two adjacent orbiting blades 2 at a time when the left one, after changing the direction of rotation due to aerodynamic forces, swivels from the original, dashed position while the right one remains in its original position due to higher friction. At the moment shown in Fig. 3a, both fan blades 2 have just contacted at point 8 of contact. The angle 1 1, clamped between the points of contact 8 with the center of rotation of each of the two fan blades 2, is acute. This creates the assumption that the fan impeller 2, which is the first to be moved, exerts a force effect on the adjacent fan impeller 2, which also triggers this. In Fig. 3b, the blade profile extends over a portion of the radial height of the fan impeller 2 into a projection 9 on the surface of which the contact point 8 is located. With this measure, the angle α (a _b <ai _a ) was reduced at otherwise identical ratios, thereby increasing the force action of the rotated fan impeller 2 to be overturned.

In Fig. 3c, at the end of the protrusion 9, a roller 16 is rotatably mounted, which rotates in case of contact with an adjacent fan blade 2, thereby facilitating its tipping.

Another solution ensuring simultaneous flipping of all fan blades 2 is shown in Figs. 4a, 4b. Giant. 4a shows an axial view and FIG. 4b shows a group of fan blades 2 in an expanded radial view, to which, at their leading edges 10, they are rotatably mounted by means of pins 12 of a connecting rod 11, which form a closed peripheral system. By means of this system of connecting rods 11, when the direction of rotation is changed, all the rotating vanes 2 are swiveled around the radially oriented pivoting axes 4 to the desired position. Alternatively, a cable connection may also serve as the link rods.

FIG. 5 shows the pivotal mounting of the fan impeller 2, in which a cylindrical pin 13 with a radially oriented pivot axis 4 formed as part of the fan impeller 2 is pivotally mounted in the fan hub 1. The reduction of the torque required to rotate the fan impeller 2 is achieved by using sliding bushes 14.

Giant. 6 shows another solution for pivotal mounting of the fan impeller 2, in which the fan hub 1 is provided with cylindrical pins 15 with radially oriented pivot axes 4 and on which the fan impeller 2 are pivoted. Reducing the torque required to rotate the fan blade 2 is again achieved by the use of sliding bushes 14.

Giant. 7 shows a detail of a cross-section of a fan in which the outer surface of the fan hub 1 in the "A" section and the inner surface of the fan hub 3 in the "B" section are formed as portions of spherical surfaces centered on the radially oriented axis 4 of the impeller blades 2 and radii r _A and r _B respectively.

The described solution according to the invention can advantageously be used in generator motors for pumping stations which have different sense of rotation in the generator and motor modes. This solution can also be advantageously applied to other reversible electrical machines.

Claims (12)

Subject An axial fan of a reversible electric rotary machine, the impeller of which is mounted on a rotor of said machine and whose impeller blades are connected to a hub by means of radially oriented axial cylindrical pins, characterized in that the 0 conventional fan blades (2) are mounted on the hub (1). ) of the fan freely rotatable, their extreme pivoting positions being defined by the stops (6). 2. An axial fan according to claim 1, the fan blades of which are on each fan radius of the symmetrical drop profile, characterized in that the blades (2) are symmetrical about the symmetry axis (18) and have a healing point with radially oriented axis 4J rotating blade (2J fan) Axial fan according to claim 1, characterized in that the connecting points of the point (8) of contact of two adjacent fan blades (2) form an angle (α of less than 90 °) with the center of rotation of each of them. An axial fan according to claim 1, characterized in that at the leading edges (10) of the fan blades (2) there are protrusions (9) at the portion of the radial height of the fan blades (2) adjacent to the fan hub (1). to form a point (8) of contact of two adjacent fan blades (2). Axial fan according to Claims 1 and 4, characterized in that rollers (16), the axis of rotation of which is parallel to the axis of rotation, are attached to the leading edges (10) of the fan blades (2) or to the projections (9) of the leading edge (10). the axis of rotation (4) of the fan blade (2). Axial fan according to claim 1, characterized in that the connecting rods (11) of all fan blades (2) are pivotably attached to the fan blades (2) at their leading edges (10) by means of pins (12). Axial fan according to claim 1, characterized in that the stops (6) defining the extreme positions of the pivoting movement of the fan blades (2) are formed by protrusions between adjacent blades on the outer shell of the fan hub (11). Axial fan according to Claim 1, characterized in that cylindrical pins (15) with a radially oriented pivot axis (4), the ends of which are pivotally mounted in the fan hub (1), are fixed in the fan blades (2). Axial fan according to claim 1, characterized in that the fan hub (1) is provided with cylindrical pins (15) with a radially oriented pivot axis (4) on which the rotating blades (2) of the fan are mounted. Axial fan according to claim 1, characterized in that the extreme positions of the fan blades (2) are asymmetrical with respect to the axial beam (7) passing through the radially oriented pivot axis (4). 11th Axial fan according to Claim 1, whose outer surface of the hub of the fan is shaped as part of a spherical surface, characterized in that the middle portion (A) of the spherical surface of the outer casing of the hub (1) of the fan radius (r _A) is at the intersection of axis (4) pivoting the fan impeller (2) and the fan axis (19). 12th Axial fan according to Claim 1, the inner surface of the throat of the fan is in the part opposite the moving blades form part of a spherical surface, characterized in that the middle portion (B) of the spherical surface of the inner surface of the neck (3) of the fan radius (r _B) is in the intersection of the axis of rotation (4) of the rotating blade (2) of the fan and the axis (19) of the fan.