The invention also relates to a method according to the pre-characterising part of claim 6.

It is known that in valves of the said type cavitation and high noise levels occur in the event of large pressure gradients in liquids.

Devices have been disclosed, for example in the European patent applications No.

87901700.2 and No. 81302496.5, which are intended to reduce the propensity to cavitation and thereby the noise level. The said devices are relatively complicated to manufacture, however, and therefore costly.

The object of the present invention is to produce a device of the said type that represents a simplification compared to the prior art. This is achieved according to the invention in that the device has the features specified in the characterising part of claim 1. Preferred embodiments are set out in the subordinate claims 2 to 5.

The device according to the invention affords a number of advantages. In manufacturing terms it is very easy to achieve high stability through the combination of intersecting walls provided with through openings. This greatly reduces the risk of vibrations occurring as a result of pressure gradients over the walls. Incoming flows, moreover, are divided up symmetrically and the divided flows"collide"with one another immediately in front of the outlet. This collision gives rise to a further pressure gradient, whilst valve damage is minimised even if cavitation should occur, due to the fact the pressure gradient is absorbed by the actual collision and consequently to a lesser extent by the valve material. In the fully opened position an approximately symmetrical flow through the valve is achieved with ensuing good noise-reducing characteristics and low pressure gradient in this position.

The characteristic features of the method according to the invention are set out in the characterising part of claim 6.

The invention will be described in more detail below with reference to the attached drawing in which figure 1 a in a diagrammatic plan view shows a valve and figure 1 b shows a longitudinal section B-B through the valve in figure la.

Figure 2a in a cross-sectional diagram shows the essentially cylindrical passage through the valve with a pair of intersecting walls according to the invention. Figure 2b shows one such wall. Figure 3a, like figure 2a, shows a passage with two pairs of walls intersecting one another in pairs, and figure 3b shows an example of a wall according to figure 3a. Figure 4a, with a diagram of a valve body in perspective view, illustrates how the through-flow through the valve body passage occurs with four walls arranged therein.

A ball valve 1 comprises a valve housing 2 with inlet 3 and outlet 4 arranged on opposite sides thereof. A valve body 5 with an essentially cylindrical passage 6 is pivotally mounted inside the housing 2. Figure la shows a shaft 5a connected to the valve body 5 for operation of the valve body 5. In the fully open position of the valve 1, the inlet 3 and outlet 4 and the passage are situated in line with one another. Figure lb also shows two ring seals 7a, 7b that provide sealing between inlet 3 and outlet 4 respectively and the valve body 5. The person skilled in the art will appreciate that in certain applications only one seal is required.

According to the invention at last one pair of intersecting w"s s s 8a, 8b, see figure 2a, and 9a, 9b and lOa, lOb see figure 3a, is arranged in the passage 6. The construction of a pair of walls, which as will be seen from figures 2a and 4 are arranged like a cross in the passage 6, will now first be explained in more detail with reference to the figures 2a, 2b and 4. The space in the passage 6 is divided up by the walls 8a, 8b into four chambers K1, K2, K3 and K4. The said chambers are located so that the chamber K1 lies nearest to the inlet 3 and the chamber K4, which is situated directly opposite the chamber K1, lies nearest to the outlet 4. The walls 8a, 8b are identical and for joining them together are provided with a slit 12, so that they can be inserted into one another. Fitted into the passage 6, the line of intersection 8c of the walls 8a, 8b coincides with the centre line 6a of the passage. As will be seen from figure 2b, the walls 8a, 8b are provided with through-slits 11, inclined in relation to the centre line 6a, preferably in such a way that the projecte lines of the slits on two successive walls in the direction of flow form a right angle with one another.

As will already have become clear, when the valve body is turned in the opening direction, the following happens: As the opening movement progresses, an increasingly larger connection is opened between the inlet 3 and the chamber K1 and correspondingly between the chamber K4 and the outlet 4. Initially therefore, a medium flows into the chamber K1, is forced through the slits 11 in the walls 8a, 8b into the chambers K2 and K3 in two essentially equal flows. The said flows are re-combined in the chamber K4 after again passing the slit openings 11 in the walls that lie between the chamber K4 and the chambers K2 and K3 respectively. The person skilled in the art will appreciate that this results in pressure gradients, viz.: 1. At the passage of the medium from the inlet by way of a small opening and into the chamber Kl.

2. At the passage of a half-flow through the slits from the chamber Kl to the chamber K2 or at the passage of the other half-flow through the slits from the chamber K1 to the chamber K3.

3. At the passage of the medium half-flows from the chambers K2 and K3 to the chamber K4.

4. At the meeting of the medium half-flows in the chamber K4, and 5. At the passage of the medium through a small opening between the chamber K4 and the outlet 4.

As the valve is increasingly opened, the effect of the intersecting walls 8a, 8b will diminish to an extent such that when the valve is fully open the effect is negligible.

The valve can therefore absorb very large pressure gradients at small opening angles and still have great capacity when the valve is fully open. This corresponds, moreover, to the characteristics of most process systems, in which a pump pressure falls with increasing capacity, just as the pressure gradient in fixed valves and pipes increases with an increased flow of medium. The fact that the walls 8a, 8b in the fully open valve divide up the flow of medium through the valve into four essentially equal flows gives the valve very good characteristics due to the symmetrical flows.

In the embodiment according to figure 3a of the device according to the invention there are, as stated, two pairs of intersecting walls, that is 9a 9b and 1 Oa, 1 Ob, which as will be seen from figure 3b are provided with circular through-bores 11'and slits 12 in order to permit assembly as indicated in figure 3a. The pairs of walls 9a, 9b and 1 osa, 1 Ob are symmetrical with their respective lines of intersection 9c, 1 Oc located on either side of the centre line 6a of the passage 6. The passage is divided up by the

walls into nine chambers, that is chamber kl, which lies nearest to the inlet 3, chambers k2-k7, chamber k8, which lies in the centre of the passage 6, and chamber k9, which lies nearest to the outlet 4. For reasons of symmetry the flows of medium in the chambers k2, k3, k6 and k7 are essentially equal and in the main half the size of the flows in the chambers kl and k9.

At a small opening angle the inlet 3 connects solely with the chamber kl and the outlet 4 with the chamber k9. The conditions are similar to what has already been explained in connection with figure 2a and figure 4, but it must be noted that in the embodiment with two pairs of intersecting walls according to figure 3a there are more points of constriction than in the embodiment with one pair of intersecting walls according to figures 2a and 4.

The constriction may naturally be adjusted by varying the number of openings in the walls defining the chambers and/or the size of the said openings. It will also be apparent that the valve body need not necessarily be spherical, and that the invention is also applicable in a spherical sector valve or in a cylindrical/conical throttle valve, provided that the passage is essentially cylindrical.

It will be realised that the device according to the invention is also advantageous in valves for regulating gas or steam flows.