NO760619L - - Google Patents

Description

Mixing valve for sanitary facilities.

The present invention relates to a mixing valve for sanitary facilities

and in particular a mixing valve for cold and hot water and with a valve system that has movable valve pistons and with a wobble plate, by means of which valve both the mixing ratio and the outflow volume can be set by means of a single operating device.

Mixing vehicles of this type are previously known. In German pa-

lit. no. 388900, a device for mixing hot and cold water is described. Here there is an inclined plate or wobble plate which can be set in an inclined position and which can also be turned around an axis and thereby acts on two intake valves, for hot and cold water, placed on diametrically opposite sides of the valve, and below the wobble plate. The total outflow volume can be regulated by changing the inclination of the wobble plate. By turning the wobble plate towards the valves for hot and cold water which are mounted on a diameter that is at right angles to the suspension axis for the wobble plate, the opening ratio of the two valves will change and thereby the mixing ratio will change.

In mixing valves for sanitary installations, it is of great importance that

a relatively large movement of the operating elements can be made for temperatures between 30 and 40° C between the outer positions for cold bg Warm setting. This temperature range, which is around the user's body temperature, must be able to be set in a simple and relatively accurate way because even small variations of 1-2° C from the desired temperature are noticeable and perhaps even unpleasant. Temperatures above 45° C or below 30° C are usually not desired for

because they feel too hot or too cold for the body.

For the previously known mixing valves, the mixing ratio has varied quite strongly with the setting of the operating lever in the temperature range 30-45° C, so that only a very small setting range of the operating device is available for the entire desired temperature range. Because of this, the desired mixing ratio will not be able to be set sufficiently precisely, and this will in extreme cases

trap could cause scalding or cold shock.

The present invention aims to eliminate the above-mentioned disadvantages and dangers and aims to provide a mixing valve which will provide an accurate and comfortable setting of the water temperature, especially in the most relevant application area between 30-45° C

This is achieved by designing the mixing valve in accordance with

the patent claims set out below.

The advantageous user characteristics achieved by means of the present invention are mainly due to the fact that the weight arms through which the wobble plate affects the valve pistons are changed by the point of contact between the wobble plate and the extension of the valve rods being moved from a diameter of the wobble plate to a preferred area along a secant of the plate, whereby a significant increase in the setting range for the operating element is achieved in the desired temperature range,<p>g where it is also achieved that an undesired change in the mixing ratio that has already been selected, when the total amount of liquid discharged is changed by a change in the inclination of the wobble plate, something that occurs with previously known devices cannot happen or only happens to a negligible extent within the preferred temperature range when the present invention is used.

To provide a clearer understanding of the present invention is shown

to the below detailed description of an embodiment and to the accompanying drawings where: - fig. 1 shows a longitudinal section through a mixing valve according to the present invention,

- fig. 2 shows the wobble plate with an indication of the contact points between

lom this and the valve rods when setting in the middle temperature range

- fig. 3 shows the wobble plate in fig. 2 but here the turn 45°,

- fig. 4 shows a valve piston with a valve seat of a different design than that shown in fig. 1, - fig. 5 is a diagram showing the amounts of hot and cold water passing through the valve as a function of the angular position of the swashplate.

In fig. 1, the valve body itself is shown by reference number 1. A neck part 2 on the valve body is designed so that the valve can be attached to a wash basin or the like by means of this and is also designed so that it can accommodate supply pipes for hot and cold water, respectively shown by reference number 3 and 4. A cylindrical valve body 5 is attached to the bottom part of the valve body in a watertight, sealed manner. Two valve pistons 6 are arranged in vertical bores in the valve body, which bores are parallel to each other and the valve pistons cooperate with the valve seats 7 and are controlled in the bores by valve rods 8 and these in turn are affected by a swashplate 9. The valve pistons 6 are biased by springs in the valve body 5 so that they seek to assume their closed state. A rotating bushing 10 is placed on the cylindrical surface of the valve body and is sealed to this by means of gaskets. In the figure, the seal is shown in the form of an O-ring. A top piece 11 is screwed onto the upper part of the valve capsule to retain the rotating bushing in its axial direction and to form the control mechanism for the valve pistons. In the top piece 11 there is an axially fixed and rotatable bushing 12 which includes a wobble plate 9. Along a secant which stands at right angles to the axis of rotation 13 of the bushing 12, the wobble plate is hinged to the bushing by means of a bolt 14. A lever 27 is provided to move the wobble plate to the desired inclined position, and this lever is held by a bolt 15, at right angles to the axis of rotation 13 along the diameter of the bushing 12, and this lever is equipped with an eccentric cam 16 which rests against the wobble plate 9 at point 22.

By raising or lowering the lever 27, the total outflowing volume will be regulated. During this movement, the eccentric cam 16 will be turned so that the inclined position of the wobble plate 9 is changed as it is rotated around the bolt 14, and thereby the position of the two spring-biased valve pistons will also be shifted to the same extent.

The valve pistons 6 have a shape that enables good flow conditions, as the bottom part 6 a is designed hemispherically, and connected to this and in the form of a tapering transition to the valve stem, there is a cone-shaped part 6 b, so that the valve pistons 6 have an almost drop-shaped shape. The tapered part of the valve pistons 6 b achieves a sealing closure against the corresponding valve seat 7 whereby the water pressure in the supply pipes 3 and 4 pushes the valve pistons in the closing direction in addition to the spring force. By turning the lever 27, the wobble plate which is connected to the lever will be rotated around its axis 13 in constant contact with the valve rods 8, so that the opening ratio of the two valve pistons 6 can be changed steplessly over the lever's entire rotation range (0-180°) from its cold position to its warm position thereby allowing a mixing ratio between hot and cold water to be effectively mixed in the mixing chamber 28 before the water flows out

of the tap with the correct temperature.

As can be seen from fig. 2, the valve rods 8 are in contact with the underside of the swash plate 9 at points 17 and 18. These points 17 and 18 are pushed so far to the side from the diameter of the swash plate and lie on an arc 19, so that the valve rods still have a secure assembly in the cylindrical the valve body. This is achieved with a displacement of around 0.45 of the radius of the arc 19. During a rotation of the lever, the valve rods will slide with their support points 17 and 18 towards the swash plate along the arc 19 which in the projection assumes a slightly elliptical shape when the swash plate is in an inclined position . In order to draw only hot or only cold water at the extreme positions of the lever (0° or 180°), the center line of the bolt 14 must be placed along a secant to the arc 19 and the distance of the chords 25 from the arc is obtained from the position of points 17 and 18 as well as the thickness of the swash plate. Therefore, the center line of the bolt must be positioned so that it is located somewhat in front of the support point of the valve rod whose valve piston is not to be opened in the extreme position.

With the help of the arrangement described above, a situation is achieved in which the opening ratio between the valve rods 6 based on the average mixing ratio (50% cold and 50% hot water) as shown in fig.2, is shifted from its initial position in relation to the rotation angles of the wobble plate< p>g is accelerated towards the end of the rotational movements in the area of the extreme positions that the lever can take in the states hot or cold. Consequently, the outflowing volume of hot<p>g cold water will be increased or decreased in this medium mixing area in the manner required to achieve an accurate and sensitive setting of the water temperature in the range between 30-45° C, in such a way that it becomes less than proportional to the angle of rotation of the swash plate and more than proportional in the areas near the extreme points of the setting possibilities.

By displacing the contact points 17 and 18 as shown in fig. 2, one will get a situation where the effective weight arms 20 and 21, shown as dashed lines in the figure, are considerably extended from the bolt 14 to the contact points 17 and 18, while the length ratio of the two weight rods (see fig. 3) changes considerably less in the middle mixing range than for a similar arrangement with the contact points along the diameter 24. Apart from increasing the sensitivity of the setting at a temperature range between approx. 30-45° C, this also leads to a negligible small change in the mixing ratio which is set and which maintains the temperature in a range between 30-45° C if there is a jump in the total amount of water flowing through the valve.

In fig. 4 shows a valve piston 6 with a different design

of the valve seat 7. Here, the valve seat 7 only has the function of providing a leak-free shut-off, in contrast to what was the case in fig. 1.

The relevant opening characteristics for the valve intakes are determined by an adjustable bushing 26 which includes the pistons 6. In the inner surface of this bushing in the opening direction and beginning slightly below the position where the valve piston makes contact with the bushing in the closing direction, recesses 27 are provided which increase in cross section. This causes the recesses 27 to only open the passage for flow to the adjustable bushing 26, when the piston 6 has sunk by a distance roughly corresponding to the distance 29, while the valve seat 7 is already wide open so that the opening characteristics are determined by the adjustable bushing alone. With a suitable choice of dimensions<p>g number of recesses, the mixing<p>g regulation functions of the mixer tap can be further improved.

The diagram shown in fig. 5, shows the flow of hot and cold water in relation to the current angular position of the wobble plate, as the flow volume per minute is marked along the ordinate while the angular rotation of the lever 2 7 is marked on the abscissa. The straight lines 20<p>g 21 show a flow volume of cold and hot water which varies proportionally with the angular rotation of the wobble plate The curves 22<p>g 23 show the measured flow value for hot

Dg cold water in relation to the angle of the wobble plate with the valve pistons arranged in accordance with the present invention. The curves which are shown in the central area of the diagram and which thus correspond to an average temperature of 30-45° C, have a very weak rise so that the water temperature can be set very precisely and with great sensitivity over a relatively large angle of rotation. In the outermost zones for cold and hot water respectively, the curves show a greater rise than what a proportional valve would give. This means that the temperature of the mixed water here changes quite rapidly with the rotation of the lever. This is also advantageous as in these extreme positions you either want only hot or only cold water anyway.

Claims (7)

1. Mixing valve for sanitary facilities and especially for mixing cold <p> g hot water, pg equipped with a vehicle system with movable valves pistons and with a wobble plate, by means of which valve both the mixture ratio <p> g the outflow volume can be set with a single operating device, characterized in that the two valve pistons ( 6 ) are displaced in relation to the diameter ( 24 ) through the pivot axis ( 13 ) of the wobble plate ( 9 ), as the valve rods ( 8 ) is in contact with the wobble plate, and that a device to influence the opening characteristics of the cold and hot water intakes is placed at the valve pistons ( 6 ) or at the valve seats (7). 2. Mixing valve according to claim 1, characterized in that the valve rods (8) contact the wobble plate (9) at contact points (17, 18) which lie on the circumference of a circle (19) and are offset from the wobble plate diameter by a distance corresponding to about 0.45 the radius of the circle (19) on which the contact points are located" 3. Mixing valve according to claims 1 and 2, characterized in that the contact points (17 and 18) between the valve rods and the wobble plate lie on the circumference of the circle (19) when the wobble plate is horizontal, and that the tilt axis (14) of the wobble plate (9) forms a secant to this circle circumference, as the chord interval (25) between this secant and the arc of the circle (19), is dimensioned so that only one valve piston (6) is opened at the maximum inclined position of the wobble plate (9) in the two extreme positions of the operating device (cold-respectively hot water ). 4. Mixing valve according to claims 1-3, characterized in that the contact points (17 and 18) between the wobble plate and the valve rods are removed so far from the diameter (24) of the wobble plate for a rotation of 60° of the wobble plate around its axis of rotation ( 13 ) is necessary to change the temperature of the mixed water from 30° - 45° C. 5. Mixing valve according to claims 1-4, characterized by a t. the valve pistons (6) in their lower area are semi-spherical (6 a), that a tapered part (6 b) whose surface cooperates with the valve seat (6 a) is attached to this lower part 7) and that this tapered part (6 b) is connected as a transition to the valve rod (8), so that the valve pistons (6) are drop-shaped and provide good flow conditions. 6. Mixing valve according to one of the claims 1-5, characterized in that each of the valve pistons (6) is surrounded by a valve seat (7) and a regulating bushing (26), with a leak-free closure provided by the valve seat (7) while the normal flow quantity is fixed - is removed by the regulating bushing (26 ). 7. Mixing valve according to claim 6, characterized in that the regulating bushing (26) which accommodates the valve pistons (6) is designed so that the inner surface of the bushing is provided with recesses (27) with an increasing cross-section in the direction of the opening, which recesses begin slightly below the place where the valve piston makes contact with the bushing in the valve's closed position.