DE1628116B1 - Impeller for a pump turbine - Google Patents

Description

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The invention relates to an impeller for through the upper end of the adjustable blade parts,

a pump turbine with adjustable impeller so that the latter are designed like flaps. These

shovel. However, the turbine is not suitable for pumping

At delivery or drop heights of more than 100 m, operation is carried out, since the impeller blade at the impeller inlet turns the pump turbines of Francis design up to now at an angle of about 90 ° with the circumferential speed, ie centrifugal machines with fixed impellers. The purpose of the adjustable shovels. Such pump turbines do not need in the blade end to achieve a general for given performance values for flow reversal, but optimal pump operation a higher speed than in a favorable regulation possibility with alternating turbine operation. Since in both operating modes the water volumes can be achieved
understandable but the same electrical machine. the same speed for both operating modes. From this, however, an improved efficiency or a conclusion for the pumping on the one hand and for the 15 has higher power, which thus combines the advantages of turbine operation on the other hand a conventional Francis impeller and those of the half-softening deteriorated compromise-effect axial Deriaz impeller .

grad. Since the impeller of such a pump turbine is based on the impeller of a pump turbine, normally designed for pump operation, the impeller blades of which are adjustable, the pump efficiency assumes the optimal 20, the invention is characterized in that in itself value. In turbine operation, the same geodetic gradient arranged according to Francis design will then _{set a somewhat lower ne} th impeller blades from a stator-side efficiency in a known manner, in that the fixed blade part and an adjoining entry into the impeller results in a shock loss, which, after both Pages pivotable blade because the flow angle of the relative speed 25 partly exist that the pivot axes with the impeller running approximately through the middle of the is much smaller than the blade angle, and length of the cross section of the pivotable blade at the impeller outlet, a loss of rotational energy is part of the pivot axes with the impeller, which is recorded by the negative circumference - The axis enclose an angle of 30 to 60 ° and the component of the absolute flow velocity is that the pivoting blade part is caused by its ability. As a result of the non-adjustability 30 with the base, which is aligned with the fixed blade part, the impeller blade can be pivoted by a maximum of 10 ° and thus the impossibility of the position. By adapting to the two different angles, the pivoting of the blade parts located at the wheel outlet in a pump turbine can be achieved at an angle of about 7 °, for example, the optimum ranges can be achieved in a pump turbine ₃₅ that, when flowing out of the impeller, there is only a reduced compromise value, turbine operation no loss-making rotation, whereas the partial load efficiencies are unfavorable. forming flow more, so that in spite of the turbine operation between the inner and outer impeller significantly greater flow yield the coronary clamped fixed wheel shovels in so far encountered in Francis turbines rotating But standzuhal- the advantage of higher loads ₄₀ energy losses are avoided and optimum th, so that pump turbines of the Francis type produce values. The swiveling of the Schäüfelteüe are suitable for large falling or conveying heights. but also has a larger one in turbine operation

There are also semi-axial pump turbines, circumferential components and a larger meridian, the so-called Deriaz or diagonal turbines, as a component of the absolute speed of the flow, their impeller blades and mostly also guide 45 at the impeller inlet, which in turn are adjustable blades. This dual regulatory _{ei nen} larger angle of inclination of Relativgeschwinlierbarkeit allows a good adaptation to the speed brings. The angle difference between the two operating modes. It is particularly important that the blade angle and the flow angle can be regulated by the impeller, because it reduces the damaging rotational flow at the impeller outlet that otherwise occurs in the door, i.e. smaller than in the Francis turbines, so that even when the turbine is in operation, the inlet shock losses during turbine operation are reduced so that they are reduced . When pivoting, the maximum turbine power is increased and the blade part between the fixed and the pivotable running pump turbine in both directions of flow forms a small gap, which works in optimal hydraulic operating conditions. Such sense as a proofreader of the boundary layer flow on semiaxial pump turbines but only works for ₅₅ of the concave blade side. The water penetrates a limited geodetic gradient usable, namely through the gap with a large kinetic because the impeller blades are only attached to a pin supported in energy from the convex pressure side in the special impeller hub, kave suction side and feeds the boundary layer for its mechanical strength high loads with fresh energy, as a result of which the formation of dead is not sufficient and because water and eddies are prevented as a result of the high levels of shovel water, so that the load increases the risk of cavitation. Closing reduce the flow losses in the impeller, borrowed is already a turbine proposed WOR Since only a portion of the impeller blades pivoted to, which are arranged according to Francis type running wheel blades lower _w i _r d and these pivotable parts exposed from a leitradseitigen solid and strains are, there can be a substantially higher conveying or falling heights than in the case of the part that can be pivoted up to this point on both sides 65. The pivot axes of herigen semi-axial pump turbines are selected and the adjustable blade parts are located in one of the. Thanks to the possibility of pivoting the normal plane of the blades to the impeller axis and if parts run, pump turbines with the impeller

wheel according to the invention with a steep gradient Can be operated at full load and under optimal operating conditions in both directions of flow, working with the same maximum power in both pump and turbine mode and thereby the full power of the electrical machine can be used. It it is possible for the pivotable blade parts to have the basic position aligned with the fixed blade part designed for pumping operation and pivoting towards the convex blade side. But it can also be pivoted to both sides, so that, for example, the adjustable Blade parts for nominal pumping operation rotated by about 3.5 ° towards the concave blade side and then when the turbine is in operation beyond the basic position against the convex blade side can be adjusted to the same angle. Provided that you take advantage of the partial blade pivoting also wants to use for partial load operation, which affects both the cavitation phenomenon and the efficiency curve has a positive effect, this can be done by further pivoting the adjustable blade parts up to at an angle of 10 ° in both directions.

The pivotable blade parts can with the help of a built in the hub, preferably hydraulic servomechanism in a manner known per se, depending on the needs of one or the other be pivoted on the other side. It is also possible with the impeller according to the invention equipped pump turbine with adjustable or fixed guide vanes. With fixed guide vanes can also be used without automatic regulation of the pivoting impeller blade parts work with an asynchronous machine, provided that the electrical network is sufficient is strong. Such a pump turbine only has to have the option of pivoting To be able to pivot blade parts hydraulically by hand into the relevant positions. Around thereby allowing the impeller to run through in the event of sudden relief or a power failure prevent, only a speed controller needs to be provided, which is triggered when a certain Limit speed swivels the pivotable blade parts into the closed position or on acts a conventional, the closing of the blades bringing about quick-action closing mechanism.

The subject matter of the invention is shown in the drawing, for example. It shows

F i g. 1 a part of a pump turbine in axial section and

F i g. 2 shows a development of a cut through the impeller following a conical surface.

The pump turbine has adjustable guide vanes 1. The impeller has a two-part inner impeller rim 2 and an outer impeller rim 3, between which impeller rims the impeller blades are arranged. These each consist of a leitradseitigen fixed part 4 and an adjoining this pivotable part 5. The pivot axes 6 of the pivotable parts 5 are inclined to the impeller axis 7 at an angle of 45 ° with the axis 6 for instance by the center of the length of the cross-section of the Blade part 5 runs. The parts 5 can, as shown in FIG. 2 reveals, are pivoted from their basic position shown in full lines to both sides by an angle of at most 10 °, the pivot positions on the convex side being intended for turbine operation and those on the concave side for pumping operation. In addition, the blade parts 5 can still be pivoted into an extreme position S , in which they close together, which position is valid for starting in pumping mode or also serves as a quick-closing position to prevent the turbine from running away.

The pivotable blade parts 5 are each with a pin 8, 9 in the inner and outer impeller rim 2,3 stored. The outer pin 9 has a water-lubricated bearing with a Bearing bush 10 made of plastic. To the gap friction loss of the rotating impeller in this To keep the area as small as possible, the sleeves 10 are together with after the pre-assembly machined the impeller rim 3, so that there is a continuous conical surface.

It is also possible to have only the fixed blade parts between the inner and outer impeller rim to be arranged and the pivotable blade parts exclusively in the inner impeller rim or to be stored in the impeller hub.

Claims (1)

Claim: Impeller for a pump turbine with adjustable impeller blades, characterized in that that in a manner known per se, the impeller blades arranged according to the Francis design (4, S) consisting of a fixed blade (4) on the stator side and an adjoining, to both sides pivotable blade part (5) exist that the approximately by the Center of the length of the cross section of the pivotable blade parts extending pivot axes (6) enclose an angle of 30 to 60 ° with the impeller axis (7) and that in each case the pivotable shovel part from its basic position aligned with the fixed shovel part is pivotable at most 10 °. 1 sheet of drawings