VALVE DEVICE

Abstract

A valve device for liquids, especially for liquid plastic constituents of single- or multiple-constituent plastic mixtures, includes a valve housing with a liquid inlet and a metering valve, which has a discharge opening that can be closed by a closure element, a pressure control device acting on the liquid in the liquid inlet and comprising a control membrane which acts on the closure element. A shut-off diaphragm separates the pressure control device from the liquid inlet, and the pressure control device comprises a fluid-tight control chamber, which is at least partially arranged in the valve housing, for a substantially incompressible fluid. A pressure generating device allows the control membrane can be subjected to pressure by an incompressible fluid arranged in the control chamber.

Description

The present invention concerns a valve device having the features of the classifying portion of claim 1 and/or the classifying portion of claim 15.

A valve device in accordance with the classifying portion of claim 1 is to be found in EP 1 123 155 B1. In that valve device the control diaphragm is actuated pneumatically, which limits the pressure range which can be used to very low pressures or requires large transmission areas.

A valve device according to the classifying portion of claim 15 is to be found in DE 195 42 797 B4. The device disclosed in that specification is of a very large structure. Control of the force storage means is effected by manual adjustment.

The object of the invention is to provide a valve device in which the above-described problems are at least partially avoided.

That object is attained by a valve device having the features of claim 1 and/or claim 15. Advantageous embodiments of the invention are recited in the appendant claims.

The provision of a control chamber which is at least partially arranged in the valve housing for a substantially incompressible fluid (for example a liquid or a highly compressed gas) makes it possible to enlarge the pressure range which can be used to much higher pressures than in the state of the art without large transmission areas being required. The invention affords pressure ranges of up to 100 bars instead of about 25 bars as in the state of the art. As the substantially incompressible fluid functions as a transmission fluid for the pressure generated by the pressure generating device, the pressure generating device can be arranged in any desired fashion in relation to the closure element, which allows advantageous structural configurations.

The provision of a controllable relief device by which the force exerted on the pressure transmission element by the force storage means can be reduced permits adjustment of the force by a control device so that manual adjustment is not required.

It should be noted that hereinafter the terms force and pressure are used interchangeably as conversion between force and pressure with a known area can be easily carried out.

Embodiments of the invention are discussed with reference to the Figures in which:

FIG. 1 shows a perspective view of an embodiment of a valve device according to the invention,

FIG. 2a shows a sectional view through the valve device of FIG. 1,

FIG. 2b shows a sectional view along section line A-A in FIG. 2a,

FIG. 3 shows a modified state of the valve device as shown in FIG. 2a, and

FIG. 4 shows a sectional view through a further embodiment of a valve device according to the invention.

FIG. 1 shows a perspective view of a proposed valve device, the sectional plane S of the sectional view of FIG. 2a being shown here.

FIG. 2a shows a valve housing 1 having a liquid feed 2 and a metering valve 3 having a discharge opening 5 closeable by a closure element 4. A liquid—for example a liquid plastic component of a single-component or multi-component plastic mixture—can be introduced into the metering valve 3 by way of the liquid feed 2.

The arrangement has a pressure control device which acts on the liquid in the liquid feed 2 or in the metering valve 3. The pressure control device includes a control diaphragm 6 acting on the closure element 4. There is provided a shut-off diaphragm 7 which separates the pressure control device from the liquid feed 2 and from the metering valve 3. The shut-off diaphragm 7 is arranged at an end of the closure element 4, that is remote from the discharge opening 5. The pressure control device has a fluid-tight control chamber 8 for a substantially incompressible fluid, the control chamber being arranged in this embodiment completely in the valve housing 1. As illustrated the shut-off diaphragm 7 is in the form of a plurality of individual diaphragms which are arranged sandwich-like. That is to be preferred over a thicker, single-layer configuration of a diaphragm. That can be effected in relation to all diaphragms.

There is provided a pressure generating device by which the control diaphragm 6 can be subjected to pressure by way of an incompressible fluid arranged in the control chamber 8.

The pressure control device includes a transmission element 24 arranged between the control diaphragm 6 and the closure element 4 for transmission of the pressure acting on the control diaphragm 6 to the closure element 4. In this example the transmission element 24 is disposed between the control diaphragm 6 and the shut-off diaphragm 7 arranged on the closure element 4. The transmission element 24 which here is of a piston shape comprises a first element portion 24a connected to the closure element 4 and a second element portion 24b connected to the control diaphragm 6. The mutually facing ends of the first element portion 24a and the second element portion 24b bear against each other (for example in moment-free relationship by way of a spherical surface arranged therebetween, not shown), so that when pressure acts on the control diaphragm 6, that pressure can be transmitted to the closure element 4 by way of the second element portion 24b and the first element portion 24a.

The pressure generating device has a pressure transmission element 10 which can be acted upon by a force storage means 9 (here in the form of a coil spring, it would also be possible to use other force storage means) and which in this embodiment is in the form of a plunger or piston. The pressure transmission element 10 acts on the control chamber 8 which here is closed off by means of a first rolling diaphragm 11.

There is provided a controllable relief device by which the force exerted on the pressure transmission element 10 by the force storage means 9 can be reduced. The controllable relief device here is in the form of a relief chamber 12 which can be filled with a fluid under pressure. In the present embodiment the fluid is air. The fluid can be introduced into the relief chamber 12 by way of a fluid opening 13 and kept under an adjustable pressure, for example by way of a proportional pressure regulator. In the illustrated embodiment the fluid acts on a shoulder 14 of the pressure transmission element 10 and thus reduces the force exerted on the pressure transmission element 10 by the force storage means 9 by an adjustable amount. The force exerted on the pressure transmission element 10 by the force storage means 9 is therefore a maximum force which can be reduced to the desired extent in accordance with the respective setting of the pressure of the fluid.

The fluid pressure in the control chamber 8 arises out of the force exerted on the first rolling diaphragm 11 by the force storage means 9, less the force acting in opposition to the force storage means 9, from the relief chamber 12. A force occurring due to the liquid which is flowing out acts on the shut-off diaphragm 7. The dimensioning of the shut-off diaphragm 7 and the control diaphragm 6 is so selected that the lower pressure of the fluid in the control chamber 8 (for example 30 bars) is in equilibrium with the greater pressure which is produced by the liquid which is flowing out (for example 90 bars). That corresponds to a transmission ratio of 1:3. If pressure fluctuations occur the shut-off diaphragm 7 and the control diaphragm 6 can move (towards the left or the right in FIG. 2a) in such a way that a fresh equilibrium is produced in the event of an increased or reduced gap between the closure element 4 and the discharge opening 5.

The present embodiment is fail-safe in relation to a failure of the pressure applied by the fluid insofar as, in the event of a failure, the discharge opening 5 is reliably closed by the closure element 4; if the pressure of the fluid in the relief chamber 12 fails then the force exerted on the pressure transmission element 10 by the force storage means 9 is not reduced. That force is of such a magnitude that it is sufficient to close the discharge opening 5 by the closure element 4.

In the illustrated embodiment the force storage means 9 is of a two-part structure: there are provided a first force storage means 91 and a second force storage means 92 which are connected in succession and which are respectively supported at a flange 16, that flange 16 being arranged on a slider 15 disposed displaceably on the pressure transmission element 10. The slider 15 is in contact with the pressure transmission element 10 by way of sliding bearings 17.

The pressure transmission element 10 has a head portion 19, wherein a second rolling diaphragm 18 is clamped between the head portion 19 and the shoulder 14.

Unlike the illustrated structure the element which seals off the control chamber 8 in relation to the pressure generating device or in relation to the head portion 19 of the pressure transmission element 10 of the pressure generating device or the element sealing off the relief chamber 12 in relation to the shoulder 14 of the pressure transmission element 10 does not have to be in the form of a rolling diaphragm. Alternatively it is possible to use flat diaphragms or piston seals.

A preferably pneumatically actuable adjusting element 20 is provided for completely closing the discharge opening 5 by means of the closure element 4. If as described above failure of the pneumatic system occurs reliable closure of the discharge opening 5 by the adjusting element 20 would not be guaranteed. The above-described fail-safe aspect however takes effect.

FIG. 2b shows a sectional view through the metering valve 3 along section line A-A in FIG. 2a. In this embodiment the closure element 4 has projections 21 which bear against an internal casing 22 of the metering valve 3 and by way of which it is secured against radial deviation in relation to the discharge opening 5 which in this case is nozzle-shaped.

It will be seen from FIG. 3 that in this example the valve housing 1 includes two valve housing portions, namely a first valve housing portion 1a and a second valve housing portion 1b which can be releasably connected to the first valve housing portion 1a. In the illustrated view the first valve housing portion 1a and the second valve housing portion 1b are shown detached from each other. The metering valve 3, the discharge opening 5, the closure element 4, the liquid feed 2 and the shut-off diaphragm 7 are arranged in the first valve housing portion 1a and the control chamber 8, the control diaphragm 6, the relief chamber 12, the pressure transmission element 10 and the force storage means 9 are arranged in the second valve housing portion 1b.

The first element portion 24a of the two-part transmission element 24 is arranged in an opening in the first valve housing portion 1a. The second element portion 24b is arranged in the second valve housing portion 1b. A free end of the second element portion 24b projects out by way of the surface of the second valve housing portion 1b. Connection of the second valve housing portion 1b to the first valve housing portion 1a can be facilitated by the free end of the second element portion 24b being introduced into the opening in the first valve housing portion 1a.

FIG. 4 shows a sectional view as in FIG. 2a illustrating a further embodiment of a proposed valve device. In this example the valve device includes a valve housing 1 which is of a three-part structure, including a first valve housing portion 1a, a second valve housing portion 1b and a third valve housing portion 1c. Arranged in the first valve housing portion 1a are the metering valve 3, the discharge opening 5, the closure element 4, the liquid feed 2, the shut-off diaphragm 7 and the first element portion 24a of the two-part transmission element 24. Connected to the first valve housing portion 1a is the second valve housing portion 1b in which the second element portion 24b, the control diaphragm 6 and a third control chamber region 8c of the control chamber 8 are arranged. The pressure generating device (pressure transmission element 10, force storage means 9), the relief device (relief chamber 12) and a first control chamber region 8a are arranged in the third valve housing portion 1c. The first rolling diaphragm 11 which is also arranged in the third valve housing portion 1c delimits the first control chamber region 8a in relation to the pressure generating device. The first control chamber region 8a is connected to the third control chamber region 8c in the second valve housing portion 1b by way of a conduit 23 which forms a second control chamber region 8b. In this example the first control chamber region 8a, the second control chamber region 8b and the third control chamber region 8c jointly form the control chamber 8 of the valve device.

LIST OF REFERENCES

• 1 valve housing
• 1 a first valve housing portion
• 1 b second valve housing portion
• 1 c third valve housing portion
• 2 liquid feed
• 3 metering valve
• 4 closure element
• 5 discharge opening
• 6 control diaphragm
• 7 shut-off diaphragm
• 8 control chamber
• 8 a first control chamber region
• 8 b second control chamber region
• 8 c third control chamber region
• 9 force storage means
• 91 first force storage means
• 92 second force storage means
• 10 pressure transmission element
• 11 first rolling diaphragm
• 12 relief chamber
• 13 fluid opening
• 14 shoulder
• 15 slider
• 16 flange
• 17 sliding bearing
• 18 second rolling diaphragm
• 19 head portion of the pressure transmission element 10
• 20 adjusting element
• 21 projections
• 22 internal casing
• 23 conduit
• 24 transmission element
• 24 a first element portion
• 24 b second element portion

Claims

1. A valve device for liquids, in particular for liquid plastic components of single-component or multi-component plastic mixtures, comprising a valve housing having a liquid feed and a metering valve having a discharge opening closeable by a closure element, a pressure control device acting on the liquid in the liquid feed and including a control diaphragm acting on the closure element, and a shut-off diaphragm which separates the pressure control device from the liquid feed, wherein the pressure control device includes a fluid-tight control chamber for a substantially incompressible fluid, that is arranged at least partially in the valve housing, wherein there is provided a pressure generating device by which the control diaphragm can be acted upon with pressure by way of an incompressible fluid arranged in the control chamber.

2. The valve device as set forth in claim 1, wherein the shut-off diaphragm is arranged at the closure element, preferably at an end of the closure element, that is remote from the discharge opening.

3. The valve device as set forth in claim 1, wherein the pressure control device includes a transmission element arranged between the control diaphragm and the closure element for transmission of a pressure acting on the control diaphragm to the closure element.

4. The valve device as set forth in claim 2, wherein the transmission element is arranged between the control diaphragm and the shut-off diaphragm.

5. The valve device as set forth in claim 1, wherein the control chamber is closed off with respect to the pressure generating device by a first seal, preferably a first rolling diaphragm.

6. The valve device as set forth in claim 1, wherein the pressure generating device has a force storage means and a pressure transmission element which can be acted upon by the force storage means.

7. The valve device as set forth in claim 6, wherein the force storage means is in the form of a coil spring.

8. The valve device as set forth in claim 6, wherein the force storage means is of an at least two-part configuration.

9. The valve device as set forth in claim 8, wherein the force storage means includes a first force storage means and a second force storage means which are connected in succession, wherein preferably the first force storage means and the second force storage means are respectively supported at a flange of a slider arranged displaceably on the pressure transmission element.

10. The valve device as set forth in claim 1, wherein the valve housing is of an at least two-part configuration.

11. The valve device as set forth in claim 10, wherein the valve housing includes a first valve housing portion and a second valve housing portion, wherein the first valve housing portion can be releasably connected to the second valve housing portion.

12. The valve device as set forth in claim 11, wherein arranged in the first valve housing portion are at least the metering valve, the discharge opening, the closure element, the liquid feed and the shut-off diaphragm.

13. The valve device as set forth in claim 11, wherein arranged in the second valve housing portion are at least the control diaphragm and the control chamber and preferably also the pressure generating device.

14. The valve device as set forth in claim 11, wherein the valve housing includes a third valve housing portion in which the pressure generating device and a first control chamber region are arranged, wherein arranged in the second valve housing portion are the control diaphragm and a third control chamber region which is connected to the first control chamber region by way of a conduit forming a second control chamber region, wherein the first control chamber region, the second control chamber region and the third control chamber region jointly form the control chamber.

15. A valve device for liquids, in particular for liquid plastic components of single-component or multi-component plastic mixtures, comprising a valve housing having a liquid feed and a metering valve having a discharge opening closeable by a closure element, a pressure control device acting on the liquid in the liquid feed, and a pressure generating device for pressure actuation of the pressure control device, in particular as set forth in claim 1, wherein the pressure generating device has a pressure transmission element which can be acted upon by a force storage means, wherein there is provided a controllable relief device by which the force exerted on the pressure transmission element by the force storage means can be reduced.

16. The valve device as set forth in claim 15, wherein the relief device includes a relief chamber.

17. The valve device as set forth in claim 16, wherein a fluid opening opens into the relief chamber, by way of which fluid opening a fluid under pressure—preferably air—can be introduced into the relief chamber.

18. The valve device as set forth in claim 16, wherein the pressure transmission element has a shoulder which delimits the relief chamber.

19. The valve device as set forth in claim 16, wherein the relief chamber is at least partially closed off with respect to the pressure transmission element by a second seal, preferably a second rolling diaphragm.