DE102023200632A1 - Valve - Google Patents

Abstract

A valve (10) has a valve element (14) and a substantially closed chamber (24) on a side of the valve element which is opposite to an inlet side (18) of the valve element which can be pressurized, characterized in that the chamber (24) has at least one outlet throttle (28) to a low-pressure side.

Description

TECHNICAL AREA

The invention relates to a valve.

STATE OF THE ART

Similar valves, such as those used in the US9638340B2 or US11428338B2 typically have a rotating valve element, also referred to as a puck, which rotates in sliding contact with at least one disk substantially about the central axis of the valve element. To ensure tightness in the event that the valve is to block a fluid flow, a valve element must always be in sealing contact with a counter element, for example the said disk. If the valve element now has to rotate in order to set a different position relative to the counter element and still be in sliding contact with it, a comparatively high friction force occurs as a result of the surface pressure necessary for the sealing contact, so that comparatively strong actuators are required. In other words, the friction values are in need of improvement, so that comparatively powerful actuators are currently used in such valves.

A valve according to EP 3 369 972 A1 for household appliances has a rotating valve disc and a slide that moves in the direction of flow to provide additional sealing in the event of a high differential pressure. However, this requires additional components, such as the slide mentioned.

Another similar valve according to the WO 2022/117143 A1 requires a comparatively large installation space.

DESCRIPTION OF THE INVENTION

Against this background, the invention is based on the object of improving such a valve with regard to the required installation space and number of individual parts and at the same time meeting the requirements.

This object is achieved by the valve described in patent claim 1.

Accordingly, this has a substantially closed chamber on a side of the valve element that is opposite a pressurizable inlet side of the valve element. The chamber is provided with at least one outlet throttle to a low-pressure side. Due to its arrangement on a side of the valve element that is opposite the pressurizable inlet side, the chamber essentially acts as a counterpressure chamber. In other words, the pressure prevailing in the chamber supports the pressing of the valve element against a counter element in order to improve the tightness. However, this additional contact pressure is advantageously only applied when it is required. This essentially corresponds to a case in which the valve element on the inlet side is subjected to a comparatively high pressure, which must be counteracted as described. An unavoidable leakage between the valve element and the counter element is essentially used to build up pressure in the described chamber. As described, fluid flows into the chamber through this leakage and presses the valve element against the counter element. In this case, the inlet or inlet pressure is greater than the pressure prevailing in the chamber. However, in the described case of a comparatively high pressure on the inlet side, the latter reduces the pressure with which the valve must be pressed against the valve seat, i.e. the counter element, by suitable measures, such as springs or the like.

The pressure prevailing in the described chamber is greater than a pressure on a low-pressure side of the valve, for example at an outlet, and fluid in the chamber can flow to a low-pressure side via the described outlet throttle. The outlet throttle thus essentially regulates the pressure prevailing in the chamber. In particular, when there is a comparatively low pressure on the inlet side, this also applies to the pressure in the described chamber, so that in this case unnecessary additional contact pressure is not applied to the valve element, the friction when the valve element moves with respect to the counter element can be kept low, and a comparatively low torque has to be applied by the actuator to move the valve element.

In the case of a comparatively high pressure on the inlet side, an equilibrium is essentially established in the form of a control in that an opening between the valve and the counter element, which allows leakage, is reduced by the counter pressure built up in the chamber, and an essentially stable leakage flow is formed into the chamber and from there, through the outlet throttle to an outlet.

It should be mentioned that the valve according to the invention can be provided in a vehicle, in particular in a cooling circuit of a vehicle. In particular, the valve according to the invention can be provided in a cooling water circuit as well as in another coolant circuit. Furthermore, the chamber described can be implemented with comparatively little effort, since it essentially only requires the limitation by a housing and, advantageously, no moving or active parts need to be arranged in the chamber. Furthermore, the chamber does not increase the required installation space or only increases it insignificantly, and the outlet throttle can also be designed in a simple manner and without additional parts, as described in more detail below.

Preferred embodiments of the invention are described in the further claims.

The actuator can advantageously be provided on the side of the chamber, so that in other words an outlet side of the valve is also preferably on the inlet side. This advantageously allows one side of the valve to be designed in an optimized manner with regard to the chamber and the connection to the actuator, while the opposite side has the necessary inlets and outlets.

A valve in which the valve element can be rotated about an axis that runs through the valve element is particularly easy to produce and is therefore preferred as a design. Such a valve element can be provided with the necessary cavities and/or openings in a simple manner, is preferably essentially disk-shaped and can accordingly be referred to as a puck.

The outlet throttle described can be efficiently formed in a housing surrounding the chamber and/or in a counter element of the valve element, for example a disk with which the valve element is in sealing contact.

Alternatively or additionally, it is conceivable to form the outlet throttle in the valve element itself.

Furthermore, the outlet throttle can be formed by simple means and efficiently as a notch or groove in one or more of the above-mentioned components.

Advantageously, the measure according to the invention enables the valve element in an initial state, ie when only the ambient pressure or the system pressure of a closed fluid circuit acts on it from all sides, to be in sealing contact with a counter element with a surface pressure of less than 0.2 N/mm ² .

The described design also advantageously allows a distance between the valve element and an actuator to be less than 30mm. The distance is measured between the section of the valve element closest to the actuator and the section of the actuator closest to the valve element. In particular, in the case of a rotary valve element, this allows a comparatively short actuator shaft, so that the torsion acting on it is reduced and the accuracy of the valve adjustment is improved.

It should be mentioned in addition that all patents in the German patent application filed on 29 December 2022 with the file number 10 2022 214 438 The features disclosed by the applicant with regard to the counter element are applicable within the scope of the present invention and are to be regarded as the subject matter of the present application.

BRIEF DESCRIPTION OF THE DRAWINGS

• 1 eine Schnittansicht wesentlicher Teile des erfindungsgemäßen Ventils,
• 2 bis 5 verschiedene Ausführungsformen des erfindungsgemäßen Ventils,
• 6 eine Draufsicht auf das erfindungsgemäße Ventil, und
• 7 ein Flowchart zur Darstellung der Wirkungsweise.

Preferred embodiments of the invention are explained in more detail below with reference to the drawings.

• 1 a sectional view of essential parts of the valve according to the invention,
• 2 to 5 various embodiments of the valve according to the invention,
• 6 a plan view of the valve according to the invention, and
• 7 a flowchart to illustrate how it works.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

As in 1 As can be seen, a valve 10 according to the invention essentially has a rotary actuator 12 and a rotating valve element 14 in the form of a so-called puck with suitable chambers and passages. In the case shown, the valve element 14 is in sliding contact with a disk 16, which is shown in more detail in the other figures. The valve element 14 has suitable chambers and deflections in order to ensure the desired fluid flows depending on the rotary position.

As mentioned, it interacts with the disk 16 shown and is pressed against it to ensure tightness on the inlet side 18. For this purpose, the disk 16 is secured to a housing 20 by means of suitable, for example, ring-shaped The housing 20 is sealed by seals 22 housed in grooves, and a chamber 24 is formed between the housing 20 and the valve element 14, the function of which is described in more detail below. To ensure tightness, in the example shown the valve element 14 is pressed against the disk 16. In the embodiment shown, two O-rings 26 are provided to seal the shaft of the valve element 14 to the outside. As can be seen in the middle area, this is connected to an outlet to prevent pressure build-up here.

As in 2 indicated by the arrow A, a comparatively high pressure can act on the valve element 14, which leads to leakage, as indicated by the arrow B. This leakage flow fills the chamber 24 with fluid and builds up a counterpressure, indicated by the arrows C, which additionally presses the valve element 14 against the disk 16. In this case, an equilibrium is established in particular by the fluid being able to flow out of the chamber 24 into an area of low pressure, as indicated by arrows D.

While in 2 illustrated embodiment, the outlet throttle 28 is formed in the housing 20, it is in the embodiment shown in 3 and 4 In the embodiment shown, the notch is designed as a notch in the disk 16. In cross-section, the notch can, for example, have an angle of approximately 45° and can be a few tenths of a millimeter deep. It should also be mentioned at this point that several outlet throttles can also be provided.

In particular, one or more outlet throttles 28 can be formed on the valve element 14, as in 5 In this case, the position of the outlet throttle 28 changes with the rotation of the valve element 14, but there may be applications in which such a design is useful and can be reconciled with the other details of the valve element 14.

It should also be mentioned that in all embodiments the pressure build-up in the chamber 24 is caused by a leakage flow. However, the pressure in the chamber can also be created by other measures, for example a separate supply line.

From the top view of 6 Finally, the essentially circular, three-dimensionally essentially cylindrical shape of the valve 10 and in particular its housing 12 emerges in the top view. In the middle is the shaft hub 30 for the connection of the actuator as in the 1 to 3 and 5 shown in the upper area.

From the flowchart of 7 In addition, the mode of operation is shown in that, when the pressure on the inlet side is sufficiently high, an internal leakage flow occurs through the gap between the valve and the counter element, which fills the chamber volume, and the gap between the valve and the counter element is reduced by the counter pressure built up in the chamber. This results in an essentially stable leakage flow into the chamber and from there through the outlet throttle to an outlet. Further explanations have been given above with reference to arrows A to D in 2 This means that the valve element only exerts a high contact pressure on the counter element when this is required to ensure that the valve is tight. When the differential pressure across the valve drops, the chamber pressure is relieved again by the throttle, allowing adjustment with a comparatively low torque.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• US 9638340 B2 [0002]
• US 11428338 B2 [0002]
• EP 3369972 A1 [0003]
• WO 2022117143 A1 [0004]
• EN 102022214438 [0019]

Claims (11)

Valve (10) with a valve element (14) and a substantially closed chamber (24) on a side of the valve element which is opposite to an inlet side (18) of the valve element which can be pressurized, characterized in that the chamber (24) has at least one outlet throttle (28) to a low-pressure side. Valve (10) after Claim 1 , characterized in that an actuator (12) is provided on the side of the chamber (24). Valve (10) after Claim 1 or 2 , characterized in that an outlet side of the valve (10) is on the side of the inlet (18). Valve (10) after Claim 1 , 2 or 3 , characterized in that the valve element (14) is rotatable about an axis which passes through the valve element (14). Valve (10) according to one of the preceding claims, characterized in that the outlet throttle (28) is formed in a housing (20) surrounding the chamber (24). Valve (10) according to one of the preceding claims, characterized in that the outlet throttle (28) is formed in a disc (16) with which the valve element (14) is in sealing contact. Valve (10) according to one of the preceding claims, characterized in that the outlet throttle (28) is formed in the valve element (14). Valve (10) according to one of the preceding claims, characterized in that the outlet throttle (28) is designed as a notch or groove. Valve (10) according to one of the preceding claims, characterized in that the valve element (14) is substantially disc-shaped, with cavities and/or openings. Valve (10) according to one of the preceding claims, characterized in that the valve element (14) in an initial state is in sealing contact with a counter element (16) with a surface pressure of less than 0.2 N/mm ² . Valve (10) according to one of the preceding claims, characterized in that a distance between the valve element (14) and an actuator (12) is less than 30 mm.

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