NL194309C - Self-regulating flow control valve for a ventilation system. - Google Patents

Description

1 194309

Self-regulating flow control valve for a ventilation system

The invention relates to a self-regulating flow control valve for a ventilation system comprising a valve body with an air passage channel with an elongated, substantially rectangular cross-section, and an elongated valve body mounted pivotally in the air passage channel for regulating the flow rate of an air flow occurring during operation through the air passageway, which valve body has a substantially L-shaped cross section with a short leg and a long leg, has a length substantially equal to the length of the cross section of the air passageway, and is pivotable about an axis of rotation which is in the in the longitudinal direction of the valve body and lies substantially in the plane of the long leg, the valve body being mounted in the valve body such that the axis of rotation runs in the longitudinal direction of the cross section of the air passage channel and that the long leg of the valve body extends mainly in the direction of the airst cream extends through the air passageway and the short leg is transverse to this airflow, the free edge area of the short leg of the valve body being bent in a direction away from the long leg and the free edge area of the long leg being bent into a towards the short leg.

Such a valve is known from French patent 1,520,620, in particular from figure 5.

The known valve is mounted such that the air passage channel, and in particular the longitudinal axis of its cross-section, is horizontal. This means that the axis of rotation of the valve body is also horizontal. The axis of rotation of the valve body is arranged with respect to the valve body such that when no external forces act on the valve body, the long leg of the valve body extends substantially horizontally and the short leg perpendicular to the long leg of the valve body extends substantially vertically downwards. When, as a result of a pressure difference between the inlet side and the outlet side of the air passage channel, a certain air flow occurs in the air passage channel, the valve body will rotate under the influence of this air flow, such that the free edge of the long leg moves upwards and the free edge of the short leg moves with the airflow until a new state of equilibrium is established, in which the forces exerted on the valve body are in balance. It is the intention that above a certain small pressure difference between the inlet side and the outlet side of the air passage channel, the air flow through the air passage channel is as constant as possible, irrespective of the pressure difference occurring between the inlet side and the outlet side of the air passage channel. In the case of ventilation systems for houses, it is desirable that above a pressure difference between the outside and the inside of the house of more than approximately 5 Pa, the flow of air flow through the ventilation system is as constant as possible, regardless of the wind pressure on the facade of the house.

The known flow control valve has the drawback, however, that at a pressure difference between the inlet side 35 and the outlet side of the air passage channel of more than about 10 Pa, an air flow can be achieved, the flow rate of which increases only slightly with an increase in the pressure difference. However, the influence of the differential pressure on the flow is still too great. Moreover, the capacity of the known flow control valve in relation to its dimensions is relatively small.

Another drawback of the known flow control valve is that without additional provisions the valve starts to swing at 40 with a certain pressure difference, so that the operation of the provision is nil at that time.

The object of the present invention is to provide an improved flow control valve of the above type.

This object is achieved by a flow control valve vein of the above type, wherein the free edge area of the short leg of the valve body is bent by an angle between 20 ° and 40 °. Preferably, the angle is about 30 °.

It has been found that with the valve according to the invention the flow of the air flow through the air passage channel at values of the pressure difference between the inlet and the outlet side of the air passage channel of more than approximately 5 Pa, an air flow with a very constant flow can be achieved, 50 even at high values of the differential pressure, while the control function already starts at approx. 1.5 Pa. Moreover, the capacity of the flow control valve according to the invention in relation to its dimensions appears to be considerably greater than with the known flow control valve.

In the following exemplary embodiment, the invention will be further elucidated on the shirt of the drawing, in which: figure 1 schematically shows a flow control valve according to the invention seen in the longitudinal direction of the air passage duct, 194309 2 figure 2 shows the flow control valve of figure 1 in a section according to the line INI and to an enlarged scale, figure 3 shows a particular practical embodiment of a flow control valve according to the invention, figures 4 and 5 show the flow control valve of figure 3, mounted on two different existing ventilation grids, and

Figure 6 shows another embodiment of a flow control valve according to the invention integrated in a suskasL

The self-regulating flow control valve 1 for a ventilation system, schematically shown in Figures 1 and 2, comprises a valve housing 2 with an air passage channel 3 and a valve body 4 pivotally mounted in the air passage channel for regulating the flow rate of an air flow occurring during operation through the air passage channel 3. air passageway, as shown in Figure 1, has an elongated, substantially rectangular cross section. In practice, the valve is mounted such that the longitudinal axis of the elongated cross section is horizontal.

The valve body 4, as shown in Figure 2, has a substantially L-shaped cross section with a short leg 5 and a long leg 6. The length of the valve body 4 is substantially equal to the length in the cross section of the air passage channel 3 The valve body 4 is pivotable about an axis of rotation 7 which runs in the longitudinal direction of the valve body and lies substantially in the plane of the long leg 20.

The valve body 4 is mounted in the valve body such that the axis of rotation 7 runs in the longitudinal direction of the cross section of the air passage channel and that the long leg 6 of the valve body 4 extends substantially in the direction of the air flow through the air passage channel indicated by arrows 8. 3 and the short leg 5 is transverse to this air flow. The axis of rotation 7 is arranged at a location 25 in the plane of the long leg 6 such that when the valve body 2 with the valve body 4 mounted therein is arranged horizontally and no external forces act on the valve body 4, the long leg 6 of the valve body 4 extends substantially horizontally and the short leg 5 of the valve body extends substantially vertically downward.

The free edge area 9 of the short leg 5 of the valve body 4 is bent in a direction away from the long leg 6 and the free edge area 10 of the long leg 6 is bent in a direction towards the short leg 5, as shown in figure 2. The angle over which the edge region 10 of the long leg 6 of the valve body 4 is bent is approximately 30 ° in the embodiment shown in the drawing. In practice, this angle will be between 20 ° and 40 °. The angle through which the edge region 9 of the short leg 5 of the valve body 4 is bent is between 20 ° and 40 ° and will preferably be about 30 °, as in the embodiment shown in the drawing.

By designing the valve body as described above, at a pressure difference between the inlet side and the outlet side of the air passage channel of more than approximately 5 Pa, an air flow through the air passage channel 3 can be achieved with a very constant flow rate.

Figure 3 shows a practical embodiment of a self-regulating flow valve 11 for a ventilation 40 system. In Figure 3, the valve body is indicated at 12, the air passageway at 13, the valve body at 14, the axis of the valve body at 17, and the direction of air flow at 18. The shaft 17 of the valve body 14 is supported at the ends by housing mounted end plates, which form the side walls of the air passageway 13. Figure 3 shows one of the end plates, the end plate 21. The bottom wall 22 of the air passage channel 13 slopes upwards in the direction of flow 18 and furthermore extends into a substantially vertical end section 23. This end section 23 is provided with a downwardly directed rib 24 for directing the air flow into the air passage channel 13. The top wall 25 of the air passage channel 13 slopes obliquely in the direction of flow 18 and is provided in the region of the valve body 14 with a rib 26 for directing the air flow through the air passage channel 13. With the embodiment of the flow control valve according to figure 50 optimal results are obtained.

For fastening the housing 12 to, for example, an existing ventilation grille, the housing 12 is provided with lips 27 and 28 which are provided at the end with cams 29 and 30 and which can cooperate appropriately with a fastening part of the ventilation grille.

In practice, such fasteners have a limited 55 and often the same standard dimensions for different types of ventilation grids, so that a flow control valve according to the invention can be mounted on different types of ventilation grids.

Figures 4 and 5 show the flow control valve 11 in Figure 3 mounted on two different ones

Claims (2)

3 194309 existing ventilation grilles 31 and 32, respectively, which can be mounted in a facade opening. Figure 6 shows another embodiment of the flow control valve according to the invention, wherein the valve is integrated in a so-called sus box. The valve body 47 again has the same shape in this embodiment as in the previously described embodiments. The walls 48 and 49 of the air passage channel 50 are slightly adapted. The top wall 48 runs horizontally, while the bottom wall 49 slopes upwards slightly. The flow control valve according to the invention can of course also be integrated in other ventilation facilities, the walls of the air duct being formed by walls of the relevant ventilation facility. In practice, it is also possible to arrange several flow control valves according to the invention directly next to each other in a ventilation facility. Self-regulating flow control valve for a ventilation system, comprising a valve body with an air passage channel having an elongated, generally rectangular cross-section, and an elongated valve body pivotally mounted in the air passage channel for controlling the flow of an air flow occurring during operation through the air passage channel, which valve body is substantially L-shaped in cross-section with a short leg and a long leg, has a length substantially equal to the length of the cross-section of the air passageway, and is pivotable about a longitudinal axis of rotation of the valve body and lies substantially in the plane of the long leg, the valve body being mounted in the valve body such that the axis of rotation extends in the longitudinal direction of the cross section of the air passageway and in that the long leg of the valve body extends substantially in the direction of the airflow through the air passageway and the short leg is transverse to this air flow, and the free edge area of the short leg of the valve body is bent in a direction towards the short leg, characterized in that the free edge area (9) of the short leg ( 5) of the valve body (4) is bent over an angle between 20 ° and 40 °. Hereby 5 sheets drawing