WO2010124755A1 - Valve for guiding fluids and metering device - Google Patents

Abstract

The invention relates to a valve (2) for conducting fluids, especially for metering fluids, through a conduit opening (12), the valve being bistable between two opening states of the conduit opening. The valve according to the invention comprises: a mobile armature (10) for opening and closing the conduit opening, which armature has at least one permanent magnet (13, 14). In order to allow reliable handling, at least one component (20), produced of a material that can be magnetized or is magnetic, is fitted to be freely mobile in a fitting device defining a dwelling volume (21). The invention further relates to a metering device (1).

Description

"Valve for fluid line and metering device"

The invention relates to a valve for fluid line, in particular for metering a fluid according to the preamble of claim 1 and a metering device for metering a fluid according to the preamble of claim 12.

From the prior art, for example, by the

DE 197 57 679 Al a device for dispensing detergent.

The object of the invention is to propose a valve or a metering device, which allow safe handling.

This object is achieved on the basis of a valve or a metering device of the aforementioned type, by the characterizing features of claim 1 and of claim 12.

The measures mentioned in the dependent claims advantageous embodiments and developments of the invention are possible.

Accordingly, a valve according to the invention is characterized in that at least one component of magnetizable or magnetic material is provided, which is mounted freely movable within an attachment device defining a retention volume.

The valve according to the invention can be used for fluid conduction, in particular for metering a fluid through a conduit opening. Fluids are Liquids or gases. The valve makes it possible, for example, to interrupt the continuation of such a fluid or to let it continue. By means of the valve, it is also possible for a certain amount of fluid to be directed through the corresponding conduit opening, which can open or close the valve. This can also be achieved by opening or closing the valve for a certain time. In this case, the valve according to the invention is formed bistable. The valve thus has two stable states, each corresponding to an opening state of the conduit opening, namely open or closed. The opening and closing of the conduit opening takes place in the valve according to the invention via a movable armature. "Bistable" in the sense of the invention means that the valve can be in one of the two states, without being connected, or that from the outside a corresponding control signal is given to the valve.

In principle, the use of permanent magnets can advantageously improve the mechanical reliability of the valve. For example, the use of springs to exert a spring force on components of the valve, such as the armature can be reduced or avoided altogether. Thus, the valve can be formed in particular corrosion resistant. In general, the permanent magnets can also be easily encapsulated. Furthermore, the use of corrosion resistant hard ferrites for the permanent magnets is possible.

Basically, in a bistable valve, there are various possibilities for making one of the corresponding states stable, in particular when the valve is not connected, that is, an active attempt is made externally to bring about a state. One possibility is, for example, to attach a spring to the armature which presses the armature in a certain direction. Furthermore, in principle, the weight of the armature could be chosen so that this - without the presence of a magnetic Force up - pulled down by gravity. However, in order to be able to exploit, for example, the magnetic force of the valve in the most non-cyclic state of the valve, in a development of the invention at least one component of magnetizable material or of magnetic material is provided. Magnetic material, such as a permanent magnet, itself generates a magnetic field and is capable of attracting or repelling another permanent magnet, eg, a permanent magnet connected to the armature.

Furthermore, however, a component of magnetizable material may also be formed, so that align the elementary magnets of the material in the field, such as a permanent magnet, and thus a force effect between the component of magnetizable material and the permanent magnet is generated. In this way, the anchor can be held in one or two stable layers; the valve can be a bistable valve by such a measure, in each case one of the permanent magnets is just attracted by the magnetic or magnetizable component stronger, which corresponds to the corresponding state to be taken of the two bistable states.

As a rule, corresponding valves or metering devices are transported, for example, from their production site to the end customer. Often the device is exposed to vibrations. But also, for example, when, for example, a dispenser located in a household appliance is taken out of its operating position, it can be shocked. In such shocks, it is advantageous for safe handling when the valve of the spout remains closed, so that the medium to be dosed can not reach the outside due to the vibration. It is particularly advantageous in a valve according to the invention that it can be designed so that the component freely movable in the accommodation volume can be replaced by such a vibration. is moved and thus the attraction between the corresponding permanent magnet of the armature and this device is lower, so that the armature can take the other, stable state of the bistable valve. In this case, so the valve could, if it was previously open, close by a shock.

Conceivable, in principle, the reverse case, namely, that for a corresponding application, it is just desirable to open by a shock valve, e.g. similar to a pressure relief valve, so that in such a case there is a connection to the environment.

A fixed attachment of one of the components to the valve means that this is for example attached to a housing of the valve or to a guide sleeve of the armature. For example, it does not move with the anchor or just as little with the free in the

Moving residence movable component, but remains static in contrast.

In one embodiment of the invention, in particular, the attachment device or the residence volume may be cylindrically shaped, so that e.g. the movable magnetizable or magnetic component can change its distance from the permanent magnet of the armature when it shakes.

In one embodiment of the invention, the armature comprises two permanent magnets, which are arranged facing each other with like poles. These permanent magnets are mounted so that they are always at a fixed distance to each other. The two permanent magnets thus generate a magnetic quadrupole field. If, for example, both permanent magnets are of the same design, the field lines have the following symmetries in their course:

- On the one hand may be a mirror symmetry with respect to an imaginary line on which the two permanent magnets are arranged and which passes through the poles of the permanent magnets. - On the other hand, a mirror symmetry with respect to an imaginary line best, which runs between the two permanent magnets and with respect to the two permanent magnets are arranged mirror-symmetrically.

Furthermore, there may be a point symmetry with respect to the intersection of the two imaginary lines mentioned above.

Especially with regard to the formation of a bistable valve, the use of a quadrupole field, in particular a quadrupole field with corresponding symmetries, may be advantageous since e.g. With respect to the symmetry in a comparatively simple way similar force effects on both sides of the axis of symmetry can be generated. In particular, the quadrupole field makes it possible for there to be practically no field in some areas between the two permanent magnets. In a bistable valve, these characteristics can be exploited to achieve two stable states, while between both states a e.g. unstable equilibrium of forces can prevail. A bistable valve further has the advantage that this energy can be saved, since to maintain one of the stable states, the valve does not need to be supplied with a permanent control signal, whereby the energy saving is possible.

In an advantageous embodiment of the invention, at least one of the two permanent magnets is fixedly secured to the anchor. This makes it possible, for example, that a force which acts as a result of the magnetic field on the permanent magnets, while also being transferred to the armature itself.

Further, in one embodiment of the invention, there is a coil which can generate a magnetic field. The generation of the magnetic field by the coil serves to move the armature. In order for this to be possible, the armature comprises at least one permanent magnet. Basically, the Generation of a magnetic field in a valve instead of a coil and a movable permanent magnet can be used. The use of a longitudinal magnet, which is moved, for example, and whose magnetic field causes a force dependent on this distance by approaching the permanent magnets of the armature, is basically possible. However, it may be particularly advantageous to use a coil for generating such an external magnetic field, which is therefore electrically connectable. In particular, the voltage applied to the coil can be reversed, and thus the direction of the field lines of the magnetic field can be reversed. By means of a coil, it is also easier to vary the field strength by adjusting the coil current, while, for example, a permanent magnet for generating the magnetic field with a motor must be approximated and removed to vary the strength of the magnetic field.

Furthermore, in a development of the invention, at least one of the permanent magnets is located inside the coil. A simple advantage that can be achieved by this measure is to be able to build a compact as possible valve. If the armature with its permanent magnets is moved by the influence of the magnetic field generated by the coil, then this arrangement has the further advantage that the field lines of the magnetic field of the coil run largely parallel inside and also inside the coil high flux density is present, ie a comparatively high number of field lines pierce a unit area. This makes it possible to improve the force on the armature or to have the highest possible force acting on the anchor. In particular, the arrangement may also be configured such that both permanent magnets are located inside the coil. At least one of the permanent magnets may also be located in the interior of the coil in any position of the armature between the opening and the closing of the conduit opening. The coil may further at least partially surround the armature.

In particular, in a development of the invention of movable armature be designed so that its movement is on the axis of the coil. For example, this is particularly advantageous when the armature is at least partially surrounded by the coil. Here, too, particular advantages in terms of compact design and in terms of increased force on the armature are possible.

In addition, in one embodiment of the invention, the two permanent magnets may be arranged on and / or about the axis of the coil. It is particularly conceivable that the axis of the coil, the axis of the armature, the line on which the permanent magnets are arranged, and the axis of movement of the armature all coincide.

In addition, the armature can be designed in one embodiment, that it has been produced to a large extent as a plastic injection molded part. However, the anchor can also be made, for example, from a stainless steel, a light metal, a composite material, etc. Therefore, it may be advantageous if the armature has a closing element for closing the conduit opening. In particular, this allows a particularly tight closure of the conduit opening. Depending on the application, the sealing material may also be correspondingly corrosion-resistant, acid- or base-resistant or temperature-insensitive. If appropriate, the closing element can also cover a part of the armature or else the entire armature on the outside in order, for example, to avoid an interaction of the anchor material with the corresponding fluid

Depending on the field of application of the valve, the anchor can be made of different materials. For example, a relatively light anchor can be made,

For example, when the coil at least partially surrounds the anchor, the recording of the coil, so the part around which the coil is wound, can also be provided simultaneously as a guide sleeve for guiding the movable armature. Again, this is particularly advantageous in terms of a compact design as possible. In addition, one of the magnetizable or magnetic components, which can hold the armature in one of its two stable states (bistsbilcs valve), be incorporated in the guide sleeve.

Furthermore, a metering device for metering a fluid is characterized in that a valve according to the invention or an embodiment or development of this valve is provided. The valve then provides the appropriate dosage. In particular, the already mentioned advantages of the corresponding valve can then be used for the metering device.

In principle, it is possible to provide the valve in a corresponding line. In addition, it is possible that the metering device already comprises a storage chamber for storing the fluid.

In addition, the metering device can also have a pre-metering chamber for portioning the fluid volume to be metered. Such a pre-metering chamber can have a number of advantages: For example, it allows a more accurate metering of the corresponding volume of fluid. Further, it allows separation of the fluid from the space located behind the conduit opening. Especially with simple or inexpensive embodiments, it may be possible that a return flow through the conduit opening can not be completely ruled out. If, however, a pre-metering chamber is interposed, this can lead to the fact that the impurities of the fluid are kept lower by reflux. In particular, therefore, in one embodiment of the invention, the storage chamber may have a connection to the pre-metering chamber.

embodiment

An embodiment of the invention is illustrated in the drawing and will be described below with reference to the figure giving further advantages and details. In detail shows

1 shows a schematic section through a metering device according to the invention.

Figure 1 shows a metering device 1 with a valve 2 and a predosing 3. The valve 2 is designed as a bistable valve.

The predosing chamber 3 in this case comprises a predosing container 4, which is of cylindrical design. The predosing container 4 is connected via an access 5 with a reservoir V. The storage container V is shown cut off in Figure 1 at the top. If this reservoir V is designed, for example, as an exchange cartridge, then e.g. the metering device 1 are inserted at a designated location by means of the access 5 there. Therefore, in Figure 1, the access 5 is chamfered so as to communicate with the reservoir V, e.g. to be able to pierce an intended foil at an opening of the reservoir V can. The access 5 leads via an opening 6 into the predosing container 4.

At the other end of the cylindrical predosing container 4, a further opening 7 is provided. In Figure 1, this opening 7 is being closed by a separator element 8 formed as a sphere, which e.g. made of plastic. The material from which the ball 8 is made is chosen to be buoyant in the corresponding fluid to be metered. However, in principle it is also possible to make the separating element buoyant by the buoyancy of a separately formed floating body.

One application of such a metering device 1, such a valve 2 or such a predosing 3, for example, an education as a metering device for cleaning substances in household appliances, such as washing machines, dishwashers or the like. Accordingly, the ball 8 is designed in this embodiment of the invention so that the material of which it is made, a sufficient ςjΘrinπe density and the floatable separating element has enough buoyancy to in the corresponding metered liquid, such as a liquid detergent, an aqueous solution the substance to be dosed or optionally floatable in water.

Furthermore, the diameter of the separating element 8 is selected so that the cross section through the center of the ball 8 corresponds to the cross section of the cylindrical Vordosierbehältnisses 4 almost. However, the diameter of the ball 8 is chosen so that it is slightly smaller than the diameter of the cylindrical container 4, so that the ball 8 can move along the axis of the cylindrical container 4, without getting stuck. Following the opening 7 is a transfer area or a valve chamber 9, which leads to the valve 2. The valve 2 itself comprises an armature 10, which in turn comprises a sealing body 11, with which an outlet opening 12 can be closed.

Consequently, the fluid line as a whole is guided so that the fluid to be metered from the reservoir V passes through the access 5 in the pre-metering chamber 3, in particular in the predosing 4, while the plastic ball 8 can rise within the cylindrical portion 4 by the buoyancy in the fluid medium , so that this ball 8 finally reaches the opening 6 and this can also close depending on the embodiment. Accordingly, the fluid can pass through the opening 7 in the valve chamber 9. Finally, the amount of fluid to be dispensed is discharged via the valve 2 through the valve chamber 9 through the outlet opening 12 and thus reaches the outside, for example into the interior of a household appliance. If the liquid to be metered is then conducted outward via the outlet 12, the ball 8 also sinks downwards with the fluid flow and again reaches the opening 7 which, depending on the embodiment, can also close it. The separating element 8 is therefore sucked down in the fluid flow, since there is not enough space between the separating element 8 and the walls of the predosing container 4 that an amount of fluid which would be sufficient for the ball 8 not to flow past can flow past would be drawn.

The anchor 10 of the bistαbiler. Valve 2 further comprises two permanent magnets 13 and 14, which are arranged opposite to each other. Both permanent magnets 13, 14 are fixedly secured to the anchor, so in particular can not change their relative distance to each other. The armature 10 is movably mounted in a guide sleeve 15. The guide sleeve 15 is made of a non-magnetic plastic. The armature plunger 16 is, apart from the permanent magnets 13, 14 and the sealing material 11, made of the same plastic as the guide sleeve 15. The guide sleeve 15 is partially wrapped by a coil 17. In this case, the axis of the coil 17 coincides with the axis of movement of the armature 10, which is otherwise characterized by a double arrow A together.

The valve 2 is, as already explained, formed as a bistable valve: It therefore has two stable states in which the outlet 12 is opened or closed. In Figure 1, the armature 10 is in its upper position, i. the outlet 12 is open and the armature 10 is located at the top stop 18 of the guide sleeve 15. Further, a ring 19 of magnetizable material (e.g., iron or magnetizable stainless steel) is inserted in the guide sleeve 15. The center axis of this magnetizable ring 19 also coincides with the axis of movement A of the armature 10.

Above the stop region 18 is a metal ball 20 made of magnetizable iron / steel in a residence volume 21. This residence volume 21 is likewise approximately cylindrical. The metal ball 20 can move substantially freely therein (apart from magnetic attraction forces). The residence volume 21 is formed by a molded plastic tub. If, for example, the entire dosing device 1 is shaken or otherwise shaken, then the metal ball 20 accordingly moves freely within the residence volume 21. In particular, the constraints imposed by the dwell volume 21 are such that the metal ball 20 moves vertically, ie, up and down in the direction A can move. The operation of the valve can be illustrated as follows:

First of all, it is assumed that the coil 17 is not traversed by a current, so even generates no magnetic field. A quadrupole field is generated by the two permanent magnets 13, 14 which are mutually oppositely directed along the axis A and which also extends (substantially) vertically symmetrically with respect to the axis A through the middle of the permanent magnets. Assuming that the armature 10 is initially in the down position, i. closes the outlet 12, this is a stable state, since in this case the permanent magnet 14 and the field generated by him magnetized the iron of the ring 19 and the resulting force action holds the armature 10 in this position, the coil 17 for this consideration should not be flowed through by a stream. The valve 2 is in terms of the iron masses of the ring 19, the ball 20, the strength of the permanent magnets 13, 14 and in terms of size and spacing ratios of the entire valve 2 designed so that this condition remains stable initially, unless the coil of a Current is flowed through and generates a magnetic field and also independent of the current position of the iron ball 20th

Now it is possible to let the coil 17 to flow through by a current, thereby a strong and thus directed magnetic field is generated, which runs in the interior of the coil practically parallel to the movement axis A, that the armature 10 is torn from its previous position and can be moved upward in the direction of the stop 18. Is the metal ball 20, as shown in Figure 1, below, i. in the direction of the stop 18, so their material is also magnetized by the field of anchor magnets.

Now, if no voltage is applied to the coil 17 and therefore no longer flowed through by a current, it ceases to generate a magnetic field. The valve 2 is, however, with respect to the iron masses 19, 20 and its distances and the strength of the permanent magnets 13, 14 formed so that the attraction between the armature and the magnetized iron ball 20 is sufficient to the armature 10 in its second stable, open position on the stop 18 to hold up. However, this condition (position of the armature in the open state) is stable for as long as the ball 20 lies against the lower stop 22 of the common room.

If, for example, the metering device 1 is shaken by a sharp blow, by a corresponding acceleration or the like (for example during the transport of the metering device), the ball 20 loses its contact with the support surface 22 and thus moves away from the

Permanent magnets 13 of the armature farther away, so the force between the ball 20 and the field of the permanent magnet

13 of the armature is no longer sufficient to hold the armature against the upper stop 18, so that this attracted by the force of gravity or by the force of attraction between the permanent magnet

14 and the magnetizable ring 19 is pulled down along the direction of movement and thus closes the outlet 12 again.

The ball 20 is in position on the support surface 22 and is still the anchor 10 in the upper, open position, ie the stop 18, but the valve can also be closed again by a voltage in the reverse direction with respect to the above voltage is applied to the coil 17 and thus generates a magnetic field, which removes the anchor from its previous position again and transported down so that it closes the outlet 12 again. During operation of the metering device or of the valve, this is the operational closure of the conduit opening 12, since generally such vibrations can not be assumed or only in special applications. If the voltage applied to the coil 17, then immediately switched off again, the attraction between the permanent magnet 14 and the ring 19 is sufficient again to keep the armature in a closed position of the outlet 12 in a stable position.

Would you go out, for example, from a Dosierausgang 12 occlusive state of the armature (ie in the lower position), this would initially stable by the interaction between the permanent magnet 14 and the ring 19 held. Next, assume that in this situation, the metal ball 20 lying on the support surface 22 WürHP one now purely mechanically, without applying voltage to the coil 17, the armature 10 against the force between the permanent magnet 14 and the ring 19 acts to push the armature 10 up against the stop 18, the attraction force between the metal ball 20 and the permanent magnet 13 would be sufficient to hold it in a stable position.

An advantage of this design is that the metering device is always closed, in particular during transport usually. If the metering device is shaken, this has the consequence that the metal ball 20 moves within the common room 21. If the coil 17 does not generate a magnetic field at this moment, then the only stable state is the one in which the armature 10 closes the outlet 12, at least if the vibrations are not so great that, if necessary, the entire metering device can be destroyed.

Thus, if, for example, in a state in which the coil 17 is not flowed through by a current and generates a magnetic field, and in which the valve 2 would be open, a sufficient vibration, for example by removing the metering device 1 from its operating range, the Ball 20 moves within the lounge 21 and thus the valve can be closed. This leads to a significant increase in safety, which is connected to the metering device 1, since with the valve closed no fluid can pass through the outlet 12 to the outside.

Since there are only two stable states (bistable) for switching the valve 2 between the open and closed states, which can also be kept in the currentless state of the coil 17, only current pulses are necessary for switching the valve 2, which flow through the coil 17 and Thus, a magnetic field that is sufficient for switching the valve is required for a short time.

The metering device 1 is oriented in the operating position so that the outlet in the direction of gravity down or the access 5 to the reservoir in the direction of gravity is at the top.

Incidentally, not only the entirety of the features of the embodiment shown in the drawing forms an invention, but also individual features or combinations of individual features can form their own inventions.

Reference sign list:

1 dosing device

2 valve

3 pre-metering chamber

4 pre-dosage container

5 access

6 opening

7 opening

8 separating element

9 valve chamber

10 anchors

11 sealing body

12 dosing spout

13 permanent magnet

14 permanent magnet

15 guide sleeve

16 anchor tappets

17 coil

18 upper stop

19 magnetizable ring

20 magnetizable metal ball

21 lounge

22 bottom stop / support surface A movement axis

V reservoir

Claims

Claims:

1. valve (2) for fluid line, in particular for metering a fluid, through a conduit opening (12) therethrough, wherein the valve is formed bistable between two opening states of the conduit opening, comprising:

A movable armature (10) for opening and closing the conduit opening,

• which at least one permanent magnet (13, 14), characterized in that at least one component (20) of magnetizable or magnetic material is provided which is mounted freely movable within an attachment device defining a residence volume (21).

2. Valve (1) according to any one of the preceding claims, characterized in that at least one component (19) of magnetizable or magnetic material is provided, which is fixedly mounted on the valve.

3. Valve (2) according to one of the preceding claims, characterized in that the attachment device (21) is cylindrical.

4. Valve (2) according to any one of the preceding claims, characterized in that the armature (10) comprises two poles of the same name with each other arranged permanent magnets (13, 14).

5. Valve (2) according to one of the preceding claims, characterized in that the permanent magnets (13, 14) fixedly secured to the armature (10).

6. Valve (2) according to any one of the preceding claims, characterized in that an element (17) for generating a magnetic field and for moving the armature is present.

7. Valve (2) according to one of the preceding claims, characterized characterized in that the element for generating a magnetic field as a coil (17) is formed.

8. Valve (2) according to one of the preceding claims, characterized in that at least one of the permanent magnets (13, 14) is in each position of the armature (10) between the two positions of the armature inside the coil (17).

9. Valve (2) according to any one of the preceding claims, characterized in that an armature guide (15) for guiding the movable armature (10) and for fixing the fixedly mounted on the valve member (19) is provided from magnetizable or magnetic material.

10. Valve (2) according to one of the preceding claims, characterized in that the armature has a closing element (11) for closing the conduit opening (12).

11. Valve (2) according to one of the preceding claims, characterized in that a guide sleeve (15) for guiding the movable armature (10) is provided, around which the coil (17) is wound.

12. metering device (1) for metering a fluid, characterized in that at least one valve (2) is provided according to one of the preceding claims for metering.

13. Metering device (1) according to one of the preceding claims, characterized in that a predosing chamber (3) for portioning a fluid volume to be metered is present.

14. Metering device (1) according to one of the preceding claims, characterized in that a storage chamber (V) for storing the fluid is present, which has a connection (5) to the pre-metering chamber (3).