Mixing valve of single lever type arranged to facilitate temporary increase of the
output flow.
Technical field
The present invention relates to a mixing valve of single lever type for liquids, e.g. hot and cold water, and of the type comprising a valve housing, arranged having two individual inlets and a common outlet for the liquids, a manually operable control means arranged to influence a valve means, preferably of ceramic type, arranged in the valve housing, whereby both volume and temperature of the discharged flow can be controlled. According to the invention, a temporary increase of discharged flow is facilitated.
Background of the invention
For example, SE, B, 449 782 discloses a previously known solution for accomplishing a temporary increase of the discharged flow, in which the control means for controlling flow volume and temperature of the liquid discharged through the outlet is arranged as a two- arm lever, the longer part comprising of a lever extending outside the valve housing and the shorter part comprising of a control means inside the valve housing, co-acting with a valve means. Said control means has a resilient tongue serving as an abutment member, co-acting with a contact surface, and said tongue, when in contact with the contact surface, is arranged to resiliently give away and to facilitate an increase of the outlet flow. The resilient contact with the contact surface facilitates a temporary increase of the discharged flow when the manually operable lever is made subject to an increased manual force, and the resilient tongue returns the lever, and thus reduces the discharged flow, when said force no longer exists.
A previously known alternative solution is disclosed in SE, T3, 0 667 941 , in which the above mentioned resilient tongue is replaced by a springloaded screw, which in contact with the contact surface is arranged to resiliently give away due to a manually applied force to the control lever and thereby facilitate a temporary increase of the discharged flow. A substantially similar solution is also disclosed in SE, T3, 0 718 534.
In these previously known solutions utilized resilient means at the inner part of the control lever result in a requirement of space, which increases the size of the upper part of the valve housing, and thereby restricts the possibility of creating an aesthetically pleasant design. It is also desirable to reduce manufacturing costs for a mixing valve having the
function of facilitating a temporary increase of discharged flow. Furthermore, previously known solutions do not facilitate possibility to modify existing mixing valves in a simple fashion in order to introduce the function temporary increase of discharged flow for same, since they require that the mixing valve, when manufactured, has been designed with the means required to accomplish intended function.
Object of the invention
The object of the present invention is to disclose a device for a mixing valve facilitating a temporary increase of the discharged flow, which removes the above mentioned disadvantages, and which can be accomplished at a very low manufacturing cost. A further major object is to disclose a solution which in a simple way facilitates introduction of the desired function (temporary increase of the discharged flow) in substantially all types of mixing valves of single lever type having a ceramic valve unit, i.e. also already sold and installed mixing valves without said function.
The mixing valve according to the invention is of single lever type and intended for liquids, e.g. hot and cold water, and of the type comprising a valve housing, arranged with two individual inlets and a common outlet for the liquids, a manually operable control member arranged to influence a valve unit arranged in the valve housing, preferably of ceramic type and having a fixed valve disc and a in relation to same rotatably and linearly movably arranged valve disc, whereby both temperature and flow volume of discharged flow can be controlled, and it is mainly characterised in that a movement transferring member joined with the movably arranged valve disc is arranged with a springloaded abutment means extending in the direction of movement for said valve disc during a flow increasing movement, after a predetermined linear flow increasing movement arranged to take up contact with the internal surface of a surrounding tubular housing or a from a central member extending contact member, during a continued flow increasing opening movement arranged to exert a force aiming to return the movably arranged valve disc to a position in which the springloaded abutment means no longer exerts any return force due to contact with the tubular housing.
Brief description of the drawings
A non-restricting example of an embodiment according to the invention is hereinafter described more in detail with reference to enclosed drawings, in which:
Fig. 1 is a side view, partly in cross-section, of a mixing valve of single lever type, including a ceramic valve unit;
Fig. 2 is a cross-sectional side view of an example of a known ceramic valve unit with included ceramic valve discs located in the position shown in Fig. 1 ;
Fig. 3 is a side view corresponding to Fig. 2, with the ceramic valve discs located in another end position;
Fig. 4 is a view of a ceramic valve unit of the type shown in Figs. 1 and 2, modified according to the present invention, and shown actuated to the position whereafter only a temporary increase of the discharged flow can be accomplished;
Fig. 5 is a view corresponding to Fig. 3, in which the ceramic valve unit is actuated to a position in which the discharged flow is temporarily increased to a maximum discharged flow;
Fig.6 is a plan view of the part in the valve unit co-acting with control member of the valve unit in order to move the movably arranged ceramic valve disc, disclosing the side which is directed towards the ceramic valve disc;
Fig. 7 is a cross-sectional view at the line VII - VII in Fig. 6; and
Fig. 8 is a view corresponding to Fig. 4, intended to illustrate an alternative embodiment according to the present invention.
Description of shown example of embodiment
Initially can be mentioned, that the ceramic valve units used for mixing valves of single lever type are in fact supplied by different manufacturers, but that a non-official standard can be regarded as existing with regard to this type of valve units, which means that function and outside measurements substantially correspond with regard to the various types that are marketed.
Fig 1 is only intended to serve as an example of a mixing valve having such a ceramic valve unit, as a complete unit denominated 1. The mixing valve comprises in known fashion a control member 2, a valve housing 3, an outlet member 4, and two inlet pipes 5
(whereof only one is shown, and the other is located behind the shown pipe 5).
A swinging movement of the control member 2 in direction upwards from the position shown in Fig. 1 results to a corresponding degree of a supply of water from the inlet pipes to the outlet member 4, whereas the mixing relationship is decided by a movement in a plane corresponding to the horizontal plane for the position shown in Fig. 1 , i.e. a plane substantially perpendicular to the plane in which the flow rate is controlled.
Within a first flow rate determining area, denominated A, there is no surveillance of the discharged flow, but when this discharged flow is exceeded (area B), the increased discharged flow is only maintained as long as a manual force is applied to the control member 2, intended to maintain same within this area (B). As soon as this application of force ceases, the control member 2 returns, and thus also the discharged flow, to what is allowed within area A.
According to the present invention, the above described temporary increase of discharged flow is accomplished by a small modification of the previously mentioned valve unit 1. A typical example of such a unit is shown in Figs. 2 and 3 in unmodified form, i.e. without the modification according to the invention facilitating accomplishing of a temporary increase of the discharged flow.
The valve unit shown in Figs. 2 and 3 includes an upper member 6, in which a controlling member 7 is pivotally attached, the lower part of which extends into an aperture arranged in a transferring member 8, which embraces a movably arranged ceramic valve disc 9 in contact with a non-movably arranged valve disc 10. A substantially tubular housing 11 is arranged surrounding the valve unit 1 , joined to a lower supporting member 12. Fig. 2 shows the valve unit 1 in a position corresponding to the position shown in Fig. 1 , and Fig. 3 in a position facilitating maximum discharged flow.
Figs. 4 and 5 show the valve unit according to Figs. 2 and 3 modified according to the present invention, and differs by a relatively simple modification of the transferring member 8, which is more detailed described with reference to Figs. 6 and 7. A tubular member 13 is arranged in said member in a through hole extending in the direction of movement from the position shown in Fig. 2 to the position shown in Fig. 3. Furthermore, a spring means 14, in the shown embodiment in the shape of a helical spring, is arranged extending between a downwardly directed edge portion at the aperture 15, into which the lower end portion of the control member 7 extends, and the bottom portion of a non-through hole in
the tubular member 13. The portion of the tubular member 13 directed towards the aperture 15 is arranged as a collar-shaped member having a larger diameter, and thus prevents that the tubular member 13 is moved further out from the transferring member 8 in relation to the position shown in Figs. 6 and 7. The free length of the tubular member 13 past the outside diameter of the transferring member 8 is arranged smaller than the distance existing between the internal wall of the housing 11 and the outside diameter of the transferring member 8 when the valve unit is in a closed position (Fig.2). Should, for example, the latter distance be 5 mm and the tubular member 13 arranged having a free length of 2,5 mm, this would result in the possibility of an initial opening movement of 2,5 mm for the transferring member 8, and thereto attached movable ceramic valve disc 9, before the outer end portion of the tubular member 13 takes up contact with the internal wall surface of the housing 11. Such a position is illustrated in Fig. 4. During a further opening movement, the contact with the internal wall surface of the housing 11 results in a displacement of the tubular member 13 towards the aperture 15, whereby the spring means 14 exerts a pressure acting to return the tubular member back to the original extending position (Fig. 5). When thus manually applied force against the control member 2 is interrupted, e.g. when a maximum discharged flow has been accomplished (according to Fig.5), the tubular member 13 is moved by the influence from the spring means 14 back to its extending position (according to Fig. 4), which in described example results in a reduction of the discharged flow by 50%.
It should be understood that accomplished flow reduction can be varied as desired by a suitable choice of free length for the tubular member 13 in relation to the maximum distance of travel for the transferring member 8. For example, when the latter distance of movement is 6 mm, and the tubular member is allowed a maximum extending length of 4 mm, the movable ceramic disc 9 automatically returns to a position corresponding to one third of fully open position when manual influence applied to the valve unit 1 is interrupted.
In the embodiment shown and described, the spring means 14 comprises of a helical spring, partly surrounded by a dead end hole taken up in the tubular member 13. Also other solutions can obviously be used which result in a substantially analogue function. The spring means 14 may thus be a suitably designed blade spring means, in which case the tubular member 13 can be arranged as a solid pin-shaped member. In such an embodiment, the spring means 14 may also be arranged attached to the pin-shaped member in a suitable fashion, and thus act as a means which restricts the free length of the pin-shaped member extending from the transferring member 8.
Furthermore, the tubular member 13 of Figs. 4 - 7 may also be arranged as a solid pin, i.e. without any dead end hole for utilized helical spring 14. By extending shown tubular member from the collar shaped abutment member by means of a smaller stud-shaped part, which can be surrounded by the helical spring 14, shown dead end hole is no longer required. However, the disadvantage of such a solution is the shorter length obtained for utilized helical spring 14.
A further modified embodiment is shown in Fig. 8, which substantially corresponds to previously shown and described embodiment, e.g. as shown in Fig. 4. However, a substantial difference is that the upper member 6 in this modified embodiment is arranged having a preferably surrounding downwardly directed collar-shaped member 16, the internal surface of which the tubular member 13 takes up contact with its outer end portion. An advantage of this modified embodiment is, that during a rotary movement intended to increase or decrease the temperature of the discharged flow, said contact surface and tubular member 13 perform a rotary movement of identical size, and the outer end portion of the tubular member 13 thus maintains a stationary position in relation to the collar shaped member 16. According to previously described embodiment, e.g. as shown in Fig. 4, such a temperature controlling movement results in that the outer end portion of the tubular member 13 is moved along the internal wall surface of the stationary tubular housing 11 , which results in certain amount of friction and wear. This is completely avoided by the modified embodiment shown in Fig. 8.
In this connection should be pointed out, that even though it can be motivated from manufacturing point of view to arrange the downwardly directed collar-shaped member 16 as a surrounding member, only a downwardly directed member having a restricted surrounding extension is in fact required, i.e. only located adjacent to the tubular member 13. As a further modification should also be mentioned the possibility to dispose of the tubular member 13 in the embodiment shown in Fig. 8, i.e. to use the spring means 14 without any surrounding tubular member 13.
The above mentioned examples of modifications of shown embodiments are only intended to show substantially equivalent solutions within the scope of the inventive thought and the following claims, and to emphasize that the invention is in no way restricted to shown and described example of an embodiment.