DE1120227B - Nozzle control slide valve for the corrosion-free throttling of currents cavitating in the slide valve, regardless of the operating conditions - Google Patents

Description

Nozzle control valve for corrosion-free regardless of the operating conditions Throttling of flows cavitating in the slide The invention relates to Nozzle control slide. Nozzle control slides are used to regulate and throttle flows in pipelines. The main parts are the slide plate and the one behind it Nozzle plate with one nozzle or several nozzles, their arrangement and cross-sectional shape determines the control characteristic.

Corrugations are caused by such slides of the usual design Cavitation occurred, which resulted in significant malfunctions. The erosions mainly concerned the valve plate and the nozzle plate, and in some cases also the valve body.

The occurrence of cavitation depends on the operating conditions. In recent years, with the transition to higher pressures, greater pressure gradients have increased and higher operating temperatures, there is also the risk of cavitation damage to the nozzle control valve.

To avoid such damage, various measures have been taken, such as Adjustment of the slide to certain operating conditions, e.g. B. full throughput, or nozzles that narrow conically in the direction of flow or division of those to be regulated Quantities, suggested. These efforts have not led to any satisfactory result, especially not with the regulation of small quantities. (The material question should be here not be discussed, as no final solution to the problem can be expected from it is.) The invention has the task of erosion due to cavitation on nozzle control slides to be avoided regardless of the operating conditions. As tests have shown, can Slide plate and nozzle plate are not considered separately in solving this problem but must be understood as a unit, hereinafter referred to as a throttle unit will; Parts of the valve body must also be included in this unit.

According to the invention, the contours of the throttle unit are up to one Tear-off edge located in the throttle cross-section, at which the flow is separated from the contour peeled off, uniformly convergent, in such a way that the flow counteracts cavitation is sufficiently stabilized. Taking into account the by the contour in front of the Tear-off edge directing the flow are the contours behind the tear-off edge according to the invention designed divergent, such that the near the tear-off edge Remove cavitation in the adjoining mixing space (drainage space) remain. Since cavitation corrosion only occurs at the end of a cavitation area is in the immediate vicinity of a wall, is due to the training according to the invention corrosion-free throttling guaranteed.

Further, according to the invention, location and waste measurement structurally necessary or directionality of the flow behind the tear-off edge advantageous kinks or less rounded portions of the contour close to the cut-off edge by a critical length limited. This critical length is the distance on which cavitation is not dangerous to corrosion after it has arisen. According to tests, it is about 5 mm. Kinks and small curves favor the onset of cavitation. They may therefore only lie within the critical length in front of the tear-off edge.

With the design of the throttle unit according to the invention, pitting due to cavitation is avoided regardless of the operating conditions of the slide. Differences in the pressure, the pressure gradient and the operating temperature do not change the flow course which is caused by the design of the contour and is essential for the corrosion-free throttling. In connection with the observation of the critical length, the design of the contours of the throttle unit ensures freedom from corrosion, regardless of the position of the slide, i. H. on the flow rate.

In an expedient embodiment of the inventive concept, the contour of the free end of the slide plate is tapered towards the lower edge and the nozzle contour is beveled from the nozzle front edge or rounded convexly with a large radius. The rear edge of the slide plate and the front edge of the nozzle form the tear-off edge. The rear edge angle of the slide plate should not be greater than 601, expediently 45 '; the leading edge of the slide plate is advantageously rounded, with the larger the radius, the larger the trailing edge angle. This ensures a sufficiently uniform convergence of the contour up to the tear-off edge. Half the widening angle of the nozzle contour at the tear-off edge should not be smaller than 301, expediently 451. This ensures that cavitation remains away from the wall in the mixing chamber.

The rear edge of the slide plate and the nozzle front edge can also be broken (e.g. to make the edges insensitive). The fracture surface must not be wider than 5 mm, expediently only 1 to 2 mm wide, so that the resulting kinks in the contour are within the critical length in front of the tear-off edge.

It is more practical to round off the edges than to break them. The contour of the slide plate is designed so that a convex curve runs between the bevel and the rear edge, the rear edge angle not being greater than a right one in order to ensure uniform convergence up to the tear-off edge. The radius of the rounding should not be smaller than a tenth of the plate thickness in order to ensure stability of the flow against cavitation up to the tear-off edge. If it is smaller, the arc length of the rounding must not be greater than the critical length.

The rounding of the nozzle front edge is expediently designed so that The front surface of the nozzle plate is kink-free thanks to the convex curve towards the tear-off edge is performed, whereby the rounding is at most a quarter circle, so that the contour converges evenly up to the tear-off edge. The radius of the rounding should, as with of the slide plate should not be less than one tenth of the thickness of the slide plate, however, the arc length must not be greater than the critical length. The attention the critical length is one of the decisive factors for corrosion-free throttling of small quantities.

According to the invention, the tear-off edge should be in the region of the highest point of the nozzle, i.e. H. the point which the rear edge of the slide plate reaches when it is fully open, lie in the front surface of the nozzle plate. The tear-off edge of the throttle unit, which is formed by the part of the rear edge of the slide plate located in front of the nozzle opening together with the tear-off edge of the nozzle, as far as it is open, is clearly defined when the slide is fully open. Undesired instability phenomena in the flow are thus avoided.

The nozzle contour can also be expanded concave behind the tear-off edge. In order to ensure that the cavitation remains away from the wall, half the widening angle at the tear-off edge must be between 45 and 90 ' . As a result, smaller edge angles are achieved at the tear-off edge, which have a favorable effect on the separation of the flow.

In a further embodiment of the invention, the valve housing is in the Design of the throttle unit included and behind the slide plate in itself usually high arched. This achieves that even under the most unfavorable Conditions also strong cavitation in the mixing space (drainage space) remains away from the wall.

The inventive design of the throttle unit can be independent from the shape of the nozzle - i7, sectional, e.g. B. Round. Slot or heart nozzle, realized will. In particular, nozzle control slide valves that have a nozzle plate with several Individual nozzles have to be designed according to the invention by following the principles of the invention can be used on gate valve and single nozzles.

An embodiment of the invention is described with reference to the schematic drawing. In a valve housing 1 there is a nozzle plate 2 and a valve plate 3 which can be displaced along the nozzle plate. The flow enters the nozzle control valve from the left. The direction of flow is indicated by an arrow.

The valve housing 1 is arched up behind the valve plate, starting from the nozzle plate, so that the connecting space (drainage space) adjoining the nozzle plate widens upwards more than in the other directions. The inlet of the valve body narrows according to the shape of the mixing space. The nozzle plate 2 is therefore shifted eccentrically downwards with respect to the inlet and outlet cross-sections of the slide housing 1.

The nozzle in the nozzle plate 2 can have a round, slit-shaped, heart-shaped or other conventional passage cross-section. The front edge of the nozzle is rounded. The rounding, which emerges from the front surface of the nozzle plate without a kink, is not quite a quarter circle of an arc length 1 and ends in a nozzle tear-off edge A. The radius of the rounding is greater than a tenth of the thickness of the slide plate, but its arc length 1 remains below the rear the tear-off edge A , the nozzle contour expands concavely with half an expansion angle a at the tear-off edge. The rounding of the nozzle leading edge and the expanding nozzle contour close to the tear bar a Abreißkantenwinkel ß one.

The concave widening of the nozzle contour, in conjunction with the rounding of the nozzle front edge, with a sufficient size of half the widening angle α, allows the tear-off edge angle β to be limited to a structurally required minimum size. Half the widening angle α is about 451, and the tear-off edge angle β is about a right one.

The rounding of the nozzle front edge runs in the area of the highest point of the nozzle in such a way that the tear-off edge A lies there in the front surface of the nozzle plate 2. By moving the tear-off edge A at the highest point of the nozzle, the expanding nozzle contour is stretched and almost straight.

The lying in front of the nozzle plate 2 slide plate 3 is rounded at its leading edge with a relatively large radius. The rounding merges into a bevel which encloses a rear edge angle y with the rear slide plate surface. The trailing edge angle y is moderately acute and thus brought to a structurally required minimum size.

The interaction of the valve plate and the nozzle creates a tear-off edge for the throttle unit. It is formed by the part of the rear edge of the slide plate located in front of the nozzle opening and the tear-off edge A of the nozzle, insofar as it is open.

The mode of operation of the arrangement described is as follows: As a result of the uniformly convergent guidance of the contours of the throttle unit up to the tear-off edge, in particular avoiding sharp bends and kinks in the contour immediately in front of the tear-off edge, cavitation can only arise in the vicinity of the tear-off edge. Even if the rear edge angle y of the slide plate is only moderately acute, there is a sufficiently uniform convergence of the contour up to the tear-off edge due to the large rounding of the slide plate front edge. By restricting the arc length 1 of the rounding of the nozzle front, in particular the occurrence of corrosion-dangerous cavitation up to the tear-off edge is suppressed, even with a small nozzle opening, i.e. H. in the regulation of small quantities.

This causes the contour of the throttle unit to be guided in front of the tear-off edge not only stabilization of the flow against cavitation in front of the tear-off edge, but also steering of the flow that is detached from the contour at the tear-off edge in the subsequent Mixing room. On the flow separation has a beneficial effect that the Trailing edge angle ", the slide plate smaller than a right one and the tear-off edge angle fl is not too blunt.

The expansion of the contour of the throttle unit behind the tear-off edge is matched to the course of the flow in the mixing space so that the cavitation in the mixing space that occurs in the vicinity of the tear-off edge remains away from the wall and therefore cannot cause any pitting. Since the tear-off edge A of the nozzle of the nozzle is located in the region of the highest point in the front surface of the nozzle plate 2, at full gate opening the tear-off edge of the throttle unit is clearly defined. As a result, the course of the flow is also clear and unsteady fluctuations are avoided, so that there is no risk of seizure even when it is fully opened. The elevation of the valve housing 1 behind the valve plate 3 ensures corrosion-free throttling even in the case of strong cavitation.

Claims (2)

PATENT CLAIMS: 1. Nozzle control valve with a valve plate serving as a throttle unit with a nozzle plate behind it, characterized in that for the corrosion-free throttling of flows cavitating in the slide valve, the contours of the throttle unit are guided uniformly convergent up to a tear-off edge and thereby stabilize the flow against cavitation , on the other hand, diverge behind the tear-off edge in such a way that the cavitation occurring in the vicinity of the tear-off edge remains away from the wall in the adjoining mixing space (drainage space). 2. Nozzle control slide valve according to claim 1, characterized in that the contour of the free end of the slide plate towards the rear edge and the nozzle contour from the nozzle front edge beveled or convexly rounded, so that the slide plate rear and nozzle front edge form the tear-off edge, the rear edge angle of the slide plate not greater than 60 ', expediently 451, and half the widening angle of the nozzle contour at the crack edge is at least 30', expediently 45 ', and the leading edge of the slide plate is advantageously rounded, with the larger the radius, the greater the trailing edge angle. 3. Nozzle control slide valve according to claim 1 and 2, characterized in that the rear edge of the slide plate and the front edge of the nozzle are broken, but the broken surfaces are not wider than 5 mm, expediently only 1 to 2 are now wide. 4. Nozzle control slide valve according to claim 1 and 2, characterized in that a convex curve runs between the incline and rear edge of the slide plate, the rear edge angle being at most a right one, the radius should not be smaller than one tenth of the plate thickness and with a smaller radius than one tenth the sheet thickness, the arc length of the rounding is not greater than 5 mm. 5. Nozzle control slide valve according to claim 1 and 2, characterized in that the front surface of the nozzle plate is guided without kinks rch convex Run ng to the tear-off edge, the rounding at most a quarter circle and the radius not less than a tenth of the thickness of the slide plate, but the arc length is not larger than 5 mm. 6. Nozzle control slide valve according to claim 1, characterized in that behind the tear-off edge, the nozzle contour widens in a concave manner, with half the widening angle being between 45 and 90 ' . 7. nozzle control slide according to one of the previous claims, characterized in that the tear-off edge in the region of the highest point of the nozzle, d. H. the point which the rear edge of the valve plate reaches when it is fully open, lies in the front surface of the nozzle plate. 8. Nozzle control slide valve according to claim 1 with a nozzle plate with several individual nozzles, characterized in that the slide plate and individual nozzles are designed according to the preceding claims. 9. Nozzle control slide according to claim 1 to 8, characterized in that the slide housing is arched up behind the slide plate in a conventional manner. Publications considered: German Patent No. 736 861.