NL1031954C2 - Device for controlling the air flow in a ventilation device. - Google Patents

Description

DEVICE FOR CONTROLLING THE AIR FLOW IN ONE

VENTILATION DEVICE

The invention relates to a device for controlling the air flow in a ventilation device, comprising an autonomously operating valve which is provided with an air flow channel of the ventilation device and which automatically adjusts the air flow opening in function of the pressure difference between the entrance and the inlet. output of the air flow channel, wherein the valve is provided to be deformed at an increasing pressure differential at a first deformation point to a maximum deformation condition.

An autonomously operating valve means a valve that is not controlled by means of a sensor or motor.

15 The pressure differences across building components, including ventilation facilities, are constantly changing due to changes in temperature differences, wind speed and direction and the use of the building (opening doors and windows, use of ventilation facilities). As a result, there is a constant change in airflow with traditional ventilation facilities. Certain grilles are equipped with an automatic adjustment of the air flow opening (through-flow section), and consequently also the air flow rate, depending on the pressure difference across the grille (the ventilation device). They are usually referred to as self-regulating. Hereinafter, a self-regulating valve is understood to mean a valve which automatically changes the passage section or the air flow opening of a ventilation device with a changing pressure difference across the ventilation device.

The self-regulating valve provides a more or less constant air flow from a certain pressure difference across the ventilation device with increasing pressure difference. The nominal pressure difference from which the airflow must be kept constant in order to regard the ventilation device for natural air supply as self-regulating, differs from country to country due to different standards or legislation; for example in the Netherlands from 1 Pa, in Belgium from 2 Pa and in France from 20 Pa. In the Netherlands, the Building Decree prescribes that the air flow through a self-regulating grid for natural air supply may not differ by more than 20% from the nominal flow rate at 1 Pa, and this over a pressure range of 1 to 25 Pa. A similar rule is applied in Belgium with regard to the nominal air flow rate at 2 Pa and a further distinction is made between classes with a certain degree of controllability as a function of the pressure difference. The strictest 5 Masse used in Belgium, apart from the difference in nominal air flow, corresponds to the requirement in the Netherlands.

A distinction can be made between self-regulating valves that are controlled with or without an actuator or motor. This invention relates to such a tipper that works without an actuator or motor (autonomously operating valve). This means that the valve serves both as a regulator and as a sensor.

On the one hand, there are such self-adjusting Meppen in the form of a flexible uniform membrane that can fold over its entire surface at pressure differences of up to 100 Pa.

For example, such a flexible membrane is described in FR 2 729 746 that can move freely, so that the air flow opening in the air flow channel is automatically adjusted depending on the pressure difference. In FR 1 527 197 and FR 2 030 547, the control of the air flow opening in the air flow channel is controlled more depending on the pressure difference due to the shape of ribs that limit the movement of the flexible membrane.

However, these systems have various disadvantages. The solution of FR 1 527 197 is a solution that meets the French requirements, where the firmness of control is important but from air pressure differences higher than 20 Pa. To be able to meet the Dutch and Belgian requirements, however, a valve must be able to react with lower air pressure differences. To deform quickly, such a Swat must on the one hand be elastic, but on the other hand it must also provide sufficient counterforce to avoid vibrations that are the result of rapid but small changes in the air pressure difference across the valve as a result of, for example, wind effects.

3

A solution to avoid the vibrations can be found in FR 2 030 547. Herein, the membrane is sufficiently elastic to deform quickly. Furthermore, the membrane is provided with extra protrusions which in turn provide the necessary counterforce. However, the drawback of such a membrane is that it requires an additional post-processing during production to provide these extra protrusions on the membrane, whereby the production cost increases.

The membrane as described in FR 2 729 746 has both the disadvantage of the membrane as described in FR 1 527 197, namely that this membrane starts to vibrate when it is sufficiently elastic to be able to react with sufficiently small pressure differences, as well as the disadvantage of the membrane as described in FR 2 030 547, namely that an additional post-processing is required for the production of this membrane, since this membrane comprises a round opening.

On the other hand, there are self-regulating valves which do not have a uniform composition, whereby they locally perform a bending movement for controlling the air flow in the ventilation device.

Such a valve is described in BE 1 011 024. Here, a provision is described for controlling the air flow in a ventilation device with a self-regulating valve, which can be oriented in a flow channel of the ventilation device, and which automatically controls the air flow through the ventilation device, depending on the air pressure difference between the kigang and the outlet of the ventilation device, between a maximum flow opening and a minimum flow opening without the use of a sensor or motor. The self-regulating valve is equipped with an elastic soft plastic profile part serving as a flexible suspension connection for stabilizing the air flow when the pressure differences are varied, and wherein the self-regulating valve with the suspension connection consists of a two-component composition of at least one hard plastic profile and an elastic soft plastic profile.

EP 0 655 587 further describes such a valve which consists of a fixed part which is connected to a flexible part on the casing of the through-flow channel. The valve can fold at the height of this flexible part.

4

In EP 1 063 384 a similar valve is described as in BE 1 001 024, wherein the valve consists of a thicker and a thinner portion, so that it will fold at the thinner portion. In order to limit the movement, wings are attached to the thicker part which determine the maximum bending angles.

The disadvantage of the self-regulating valves described above is that the controllability i.f.v. the pressure difference is too small, resulting in unnecessary energy consumption and draft nuisance. This means that an insufficient constant flow rate is achieved with low pressure differences from 1 Pa or that the air flow rate still varies too strongly with an alternating pressure difference above the nominal pressure difference.

This problem is solved in EP 1 568 947, in which an autonomously operating valve 15 is described which is rotatably suspended around a free suspension point in the airflow channel and is designed such that the valve moves in the airflow channel with increasing pressure difference by first rotating around the free flow channel suspension point to a maximum angle of rotation and then deform without further rotation around the free suspension point.

20

The object of the invention is therefore to provide an alternative device for controlling the air flow, from 1 Pa (the Netherlands) and 2 Pa (Belgium), in a ventilation device according to the preamble of the first claim, wherein the air flow in the device is kept as constant as possible with an increasing pressure difference.

25

This object is achieved by providing a device for controlling the air flow in a ventilation device, comprising an autonomously operating valve which is movably provided in the air flow channel of the ventilation device and which automatically adjusts the air flow opening in the air flow channel in function of the pressure difference between the inlet and the outlet of the air flow channel, wherein the valve is provided to be deformed first at a rising pressure difference at a first deformation point to a maximum deformation condition, and then further deformed at a second deformation point .

5

In this way, as in EP 1 568 947, with an increasing pressure difference, from 1 Pa (the Netherlands) and 2 Pa (Belgium), the air flow in the device is kept virtually constant. The greater the pressure difference across the valve, the smaller the air flow opening becomes at the level of the valve. Furthermore, in this way the flow rate remains within an acceptable limit of the nominal flow rate, so that no extra energy loss occurs due to over-ventilation and, moreover, no draft nuisance occurs. This means that a high class of controllability as a function of the pressure difference is obtained in this way.

10

In a special embodiment of a device according to the invention, the valve is provided for further deformation at the second deformation point without further deformation around the first deformation point.

Preferably, the first deformation of a device according to the invention starts at a pressure difference from 1 Pa. This then meets the Dutch requirements.

The maximum deformation with the first deformation is preferably achieved with an air pressure difference of 5 Pa.

20

In a preferred embodiment of a device according to the present invention, the deformation of the valve takes place at the level of elastic connecting parts which are provided between two less elastic parts.

In a more preferred embodiment of a device according to the invention, a protrusion is provided in the ventilation device which determines the maximum deformation of the first deformation of the valve.

In a particularly preferred embodiment of a device according to the invention, the deformation of the valve takes place by means of a folding of the valve, wherein the deformation points consist of folding points.

A special embodiment of the device according to the invention is obtained by hanging the valve securely in the ventilation device.

6

In a preferred embodiment of a device according to the invention, the valve is made of plastic.

This invention will now be further elucidated on the basis of the following detailed description of a preferred device for controlling the air flow in a ventilation device according to the invention. The purpose of this description is only to provide a clarifying example and to indicate further advantages and details of this device according to the invention, and can therefore in no way be interpreted as a limitation of the scope of the invention or of the claims defined in the claims. claimed patent rights.

In this detailed description reference is made to the accompanying drawings by reference numerals, wherein figure 1 represents a cross-section of a ventilation device provided with a device according to the invention; figure 2 represents a cross-section of the ventilation device as represented in figure 1, wherein the self-regulating valve is deformed at the first deformation point to the maximum deformation condition; figure 3 represents a cross-section of the ventilation device as represented in figure 1, wherein the self-regulating valve is further deformed at the second deformation point after reaching the maximum deformation condition; - figure 4 represents a graph in which the flow rate (l / s) is plotted as a function of the pressure difference (Pa), wherein: in curve A the flow rate is plotted as a function of the pressure difference with a non-self-regulating grid; In curve B the flow rate is plotted as a function of the pressure difference in a ventilation device according to the state of the art; In curve C the flow rate is plotted as a function of the pressure difference with a ventilation device according to the invention.

7

A ventilation device (1) as represented in Figures 1 to 3 comprises an air flow channel (2) in which an autonomously operating valve (3) (also referred to as a self-regulating valve) is provided. This self-regulating valve (3) automatically adjusts the air flow opening in the air flow channel (2) in function 5 of the air pressure difference between the inlet (4) and the outlet (5) of the air flow channel (2). The valve (3) is thereby fixedly suspended in the air flow channel (2). In this embodiment of a ventilation device as represented in Figures 1 to 3, the valve (3) is fixedly suspended in a rail-shaped cavity (13) made in the housing (6) of the ventilation device 10 (1).

As shown in Figure 2, the self-regulating valve (3) is provided to be deformed at a rising pressure difference at a first deformation point (7) to a maximum deformation. After deformation at the level of the first deformation point (7) to a maximum deformation, the valve (3) can be further deformed at the level of a second deformation point (8), as represented in figure 3. The deformation of the valve (3 ) preferably takes place at the level of elastic connecting parts (7, 8) provided between two less elastic parts (9, 10; 10, 11). The deformation points (7, 8) are therefore preferably designed as elastic connecting parts. In the ventilation device as represented in Figures 1 to 3, a protrusion (12) is provided which determines the maximum deformation of the first deformation of the valve (3).

The first deformation starts with an air pressure difference from 1 Pa. The maximum distortion with the first distortion, as represented in Figure 2, is achieved around an air pressure difference of 5 Pa.

The deformation of the valve (3) is preferably done by pleating. In this way the deformation points (7, 8) are pleat points and the maximum deformation state (as represented in figure 3) is a maximum pleat angle.

As can be seen from Figure 4, with a ventilation device that is not provided with a valve that automatically adjusts the air flow opening in the air flow channel as a function of the pressure difference between the input and the output of the (flow-through channel) called air-regulating grid), the air flow rate increases with an increasing pressure difference In prior art ventilation devices which are provided with a valve that automatically adjusts the air flow opening in the air flow channel in function of the pressure difference between the inlet and the outlet of the air flow channel, as described for example in BE 1 011 024, the air flow rate rises to ± 35 dm3 / s at a pressure difference of 12 Pa, and then remains reasonably constant With a ventilation device (1) equipped with a device according to the In this invention, the air flow rate remains substantially constant at 20 dm 3 / s within the ± 10% limits from a pressure distant peel of 2 Pa. The faster (= with lower pressure differences) operation of the valve (3) of a device according to the invention compared to existing devices of the prior art is clearly visible.

The valve (3) according to the invention is preferably manufactured from plastic such as PVC, but can also be any other material.

Such ventilation devices (1) which are provided with a device according to the invention can be applied to or under the glass of a window or a door, on the window profile itself or in the wall.

1031954

Claims (9)

Device for controlling the air flow in a ventilation device (1), comprising an autonomously operating valve (3) which is provided with an air flow channel (2) of the ventilation device (1) and which automatically adjusts the air flow opening as a function of the pressure difference between the inlet (4) and the outlet (5) of the airflow channel (2), wherein the valve (3) is provided to be deformed with a rising pressure difference at a first deformation point (7) to a maximum deformation, characterized in that the valve (3) is provided for further deformation at a height of the first deformation point (7) to a maximum deformation at a second deformation point (8). Device according to claim 1, characterized in that the valve (3) is provided for further deformation at the second deformation point (8) without further deformation at the first deformation point (7). 3. Device as claimed in claim 1 or 2, characterized in that the first deformation starts with an air pressure difference from 1 Pa. Device according to one of claims 1 to 3, characterized in that the maximum deformation is achieved with the first deformation around an air pressure difference of 5 Pa. 25 Device according to one of claims 1 to 4, characterized in that the deformation of the valve (3) takes place at the height of elastic connecting parts (7, 8) provided between two less elastic parts (9, 10, 11). 30 Device according to one of claims 1 to 5, characterized in that a protrusion (12) is provided in the ventilation device which determines the maximum deformation of the first deformation of the valve (3). 1031954 Device according to one of claims 1 to 6, characterized in that the deformation of the valve (3) takes place by means of a folding of the valve (3), the deformation points (7, 8) consisting of folding points . Device according to one of Claims 1 to 7, characterized in that the valve (3) is fixedly suspended in the ventilation device. Device according to one of the preceding claims, characterized in that the valve (3) is made of plastic. 1031954.