NO801781L - VALVE. - Google Patents

Abstract

Valve for use e.g. in a water tap, comprising a manually movable spindle (2), and a sealing element (12) intended to move in the longitudinal direction together with the spindle to open or close the valve, which sealing element has a head with a surface (14) in in the form of a cone or truncated cone forming an extension of the spindle, as well as a fluid inlet with a conical surface (20) having the same cone angle as the closing element. The flow of fluid through the valve seat is coaxial with the center line of the closure member. and is controlled by the distance between the conical surfaces (14, 20), and when the valve is closed the flow is closed by a continuous contact surface (A) between the conical surfaces, the rotation of the closing element (12) together with the spindle (2) ceasing immediately when it occurs such contact.

Description

The present invention relates to a valve for regulation

of fluid flow.

A valve according to the invention is intended for use

in faucets for water supply, but it will be understood that the invention is not limited to this. It is common for water taps to include a rotatable element. ;which forms a piston which contacts a valve seat to close in-

the race. Usually a rigid but somewhat yielding sealing ring is provided, which when worn makes it necessary to replace it to prevent water leakage. Many attempts have been made to avoid this disadvantage and to arrive at taps without a sealing ring. So far, however, these attempts have not been particularly successful.

The present invention thus relates to a valve for regulating fluid flow, comprising a spindle which can be screwed inside a housing for longitudinal movement inside the housing, as well as a sealing element arranged to move in the same direction as the spindle to move the sealing element from the closed position, and the valve is characterized by the sealing element comprising a head with a surface in the form of a cone or truncated cone which forms an extension of the spindle, and

a fluid inlet bounded by an annular valve seat with a conical contact surface that has the same cone angle as the head of the spindle, and the parts are arranged in such a way that the flow of fluid in through the valve seats is coaxial with the center line of the sealing element and is regulated by setting the distance

between the conical surfaces, as the fluid flow is stopped

due to the contact between the cone surfaces when the valve is closed, and the rotation of the sealing element together with the spindle ceases when such contact occurs.

The head of the sealing element and the valve seat can be manufactured with high accuracy, from steel, brass or any other suitable metal or alloy, but it is often considered too expensive to produce in large numbers for sale articles of this type manufactured with high precision. Therefore, it is desirable that one of the parts is made of, e.g. hard but somewhat compressible plastic materials. Consequently, the head of the sealing element can be made of e.g. of nylon or another material with similar properties, including that it does not absorb water, and which preferably has dimensional stability at the water temperatures that usually occur, e.g. 2 •- 90°C. The use of, for example, nylon provides satisfactory properties at pressures where a normal sealing ring in a valve would be destroyed.

The head of the sealing element can have the shape of a truncated cone,

with a flat or mainly flat end towards which the fluid flows, so that the fluid hits the flat end. In order to

open the valve, the spindle is turned so that it moves in a direction away from the valve seat. The water pressure in the inlet lifts the sealing element until the valve is closed again.

Preferably, the sealing element also comprises a rod which is inserted with clearance in a bore formed axially in the spindle.

This helps to keep the sealing element coaxially aligned

in relation to the valve set during closing of the valve. The rod has clearance in the bore so that the rotation of the sealing element in relation to the spindle should cease when the sealing element comes into contact with the valve seat and so that the sealing element should be self-centering when it approaches the valve seat.

The rod preferably has such a length that when the valve is

fully open, the rod is still inside the bore.

In some countries, there are public regulations which stipulate that the sealing element or an equivalent element must be held positively by the spindle. To comply with such regulations, the rod can be retained in the bore, but without

to be in fixed connection with the spindle.

The pitch in the threads for the screw movement of the sealing element

in relation to the spindle may vary, but need not be different from what is standard for most valves and taps of this type. It has been found that a suitable taper angle for the sealing element, i.e. the angle between the cone surface and the center line can be in the range 12 - 20°, preferably

15°. Experiments have shown that this area provides optimal flow and a satisfactory contact zone between the surfaces, with a width of at least 5 mm.

It will be understood that the invention can be used not only for

new taps, since parts can also be manufactured that can be adapted to existing taps and valves. These parts can include a sealing element that replaces the piston that holds the sealing ring as well as a valve seat that can be mounted in the mouth of the inlet pipe when this is axially aligned with the spindle and the sealing element.

In the following, examples of valves according to the invention will be described. It will be understood that the description, which has been made with reference to the attached drawings, only applies to exemplary embodiments without any limitation of the scope of the invention. Fig. 1 shows a first embodiment of a valve according to the invention, seen from the side and partially in section.

Fig. 2 shows another embodiment shown in the same way.

Fig. 3 shows the parts in fig. 1 arranged in an ordinary water tap.

Fig. 4 shows a section of fig. 3 on an enlarged scale.

Fig. 5 shows another embodiment of a sealing element.;

Fig. 1 shows a spindle 2 for a valve for use in a water tap,

and the spindle has external threads 4 to screw into a valve housing 6 (shown in fig»3). An axial bore 8 is arranged inside the threaded part; part 4, and a rod 10 on a sealing element 12 is introduced into the bore. The rod has clearance in the bore,

in the example shown 0.01 mm.

The sealing element 12 also comprises a head in the form of a truncated cone, with a surface 14 that forms an angle of 15° with the axial

in

center line of the sealing element .12, as well as a flat end surface 16 .

An inlet pipe 18 for water has a mouth with a surface 20

which is designed to match the taper angle of the surface 14

on the sealing element 12. When the sealing element is fully inserted into the mouth, there is a wide, continuous contact area A with height X, and in the example shown this corresponds to 5 mm measured in the axial direction. Fig. 2 shows the same parts as shown in fig. 1, the only difference being that in order to comply with public regulations, an annular groove 22 is provided in the rod 10', so that a part 24 projecting inside the bore 8 engages with the groove to keep the sealing element 12 locked in the bore, but not to hold it firmly. Fig. 3 shows the valve parts in fig. 1 or 2 mounted inside a valve housing 6 which is placed in a crane 26 shown with dashed-dotted lines. The lower part of the faucet 26 is joined to the valve housing, and comprises a spout 28 through which water flows out of the faucet when the sealing element 12 is raised while the valve is open.

The conical surface 20 in the pipe mouth which forms the valve seat for the sealing element is shown as part of a sleeve which is fixed inside the pipe mouth 18. When water flowing upwards thus hits the flat end surface 16 of the sealing element 12,

it may be desirable for the sealing element 12 to have a conical head 30 with a tip 31 directed towards the inflowing water.

When the valve is closed, the entry of the sealing element 12 into the valve seat which is formed by the cone surface 20 is ensured by the edge 32 of the valve seat being chamfered, as shown in fig. 4. So

as soon as there is contact between the surfaces 14 and 20, the sealing element, which has rotated together with the spindle 2, will cease to rotate. Continued rotation of the spindle 2 means that the sealing element is pressed against the surface 20 and causes sealing, but because there is no turning movement between the surfaces 14 and 20, no significant wear occurs in these surfaces, so that the disadvantage of leaks and the need to change the sealing ring is avoided , as is necessary for ordinary water taps.

Claims (7)

1. Valve for regulating fluid flow, comprising a spindle which can be screwed into a valve body to move in the longitudinal direction thereof, and a sealing element arranged to move in the same longitudinal direction together with the spindle in a closing movement, characterized in that the sealing element comprises a head with a surface in the form of a cone or truncated cone that projects into the extension of the spindle, that a fluid inlet forms an annular valve seat with a surface in the form of a truncated cone and the same cone angle as the head, on the sealing element, the fluid inlet through the valve seat; is coaxial with the center line of the sealing element, and the fluid flow is regulated by the distance between the conical surfaces, in that the flow is stopped in the closed state of the valve by the surfaces having mutual contact along a continuous area, and that the rotation of the sealing element together with the spindle ceases when such contact occurs. 2. Valve as specified in claim 1, characterized by the fact that the head of the sealing element has the shape of a truncated cone and has a flat or mainly flat end surface that fluid flows hit after the inlet. 3. Valve as specified in claim 1 or 2, characterized in that the sealing element comprises a rod, and that the spindle has a bore into which the rod is inserted with a certain clearance. 4. Valve as stated in claim 3, characterized in that the rod is prevented from moving out of the bore, without being held firmly, so that the sealing element moves together with the spindle in the opening movement, regardless of the pressure in the fluid that flows in through the inlet. 5. Valve as specified in requirements 1-4, characterized in that the sealing element is made of a slightly compressible plastic material. 6. Valve as stated in claim 1, characterized by . that the cone angle, i.e. the angle between the cone surface and the center line, until the sealing element is in the range 12 - 20°. 7. Valve as stated in claim 1, characterized in that the width of the continuous contact area between the cone surfaces is not less than 5 mm.