FI90140B - VENTILATIONSVENTIL - Google Patents

Description

90140

Ventilation valve 5

The invention relates to a ventilation valve comprising a first slat part and a second slat part, at least one of which is linearly movable to reduce or increase the flow gap between the slat parts.

Ventilation valves are already known, in which the ventilation valve comprises two profile parts, i.e. control slats, which are movable relative to each other. In known ventilation valves, the flow cross-section between the louvre parts 15 is adapted to increase with respect to the flow direction. This arrangement does not guarantee the best possible air travel.

The object of the invention is a ventilation valve, in which the ventilation valve-20 brick comprises a wide adjustment range, which enables the use of a device of the same size class in different objects. The object of the invention is precisely such a ventilation valve which is easy to measure and adjust. It is an object of the invention to provide a ventilation valve which has advantageous aerodynamic properties and in which resonance phenomena are avoided.

The object according to the invention has been achieved with a device solution, one of the basic ideas of which is to make the flow paths between the slats narrower with respect to the flow direction of the air flow. At least the second slat part is displaceable and thus the device according to the invention is adjusted by moving said slat part linearly, whereby the angle α of the straight flow surface of the slat with respect to the central axis X of the flow paths remains the same. Within the scope of the invention, there is also a possible embodiment in which the two slat parts are displaceable linearly with respect to each other.

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The ventilation valve according to the invention is mainly characterized in that the ventilation valve comprises a control part which can be detachably fastened to the housing part of the ventilation valve, and that the control part

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sa has at least two body parts between which the louvre parts are connected, the body part comprising a plate part perpendicular to the longitudinal axis of the duct part of the ventilation valve, by means of which the drive wheel abutment surface at each end of the slat part, the slat part being linearly displaceable as the movement of the slat part is applied evenly to both ends of the slat part.

The invention will now be described with reference to some preferred embodiments of the invention shown in the figures of the accompanying drawings, to which, however, the invention is not intended to be exclusively limited.

Figure 1A is an axonometric view of the ventilation valve 15 according to the invention assembled.

Fig. 1B is an axonometric view of the ventilation valve according to the invention with the removable base parts separated.

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Figure 2 shows an axonometric view of the ventilation valve according to the invention with the front cover plate removed.

Figure 3A is a schematic view of a ventilation valve according to the invention. The view is taken mainly along the section line I-I in Fig. 2 and the view is simplified with respect to Fig. 2. The operating position of the valve implementing the maximum air flow is shown.

Fig. 3B shows the valve of Fig. 3A in the operating position implementing the minimum air flow.

Figure h shows the operation diagram of the ventilation valve.

Figure 5A shows the first preferred position of the adjustment scale.

Figure 5B shows another preferred location of the adjustment scale.

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Figure 6A shows the slat part in an axonometric view.

Figure 6B is a section II-II of Figure 6A.

Figure 1A shows the ventilation valve 10 according to the invention assembled. The direction of the air flow is indicated by the arrow L. In the figure, the brochure comprises a ventilation valve 10 with a jacket part 11 to which a front cover 13 is attached. The front cover 13 comprises a front part 13a and edge parts 13b. The entire front cover 13 is preferably formed of a similar structure 10 and comprises flow openings 13c, which may be in the form of e.g. slots, holes, etc. The front cover 13 may also be formed of a structure comprising a planar apertured plate portion in front of the slat parts. A flow gap or slots are then formed between the edges of the plate part and the collar of the jacket part 11. In this solution, the front cover 13 may be attached to the casing part 11 by cantilevered irons or other similar arrangements.

Figure 1B shows the ventilation valve with the detachable central parts separated. The ventilation valve 10 comprises 20 a jacket part 11 and a control part 12 which can be fastened to it, and a further removable front cover part 13.

. . The jacket part 11 comprises a channel part 14 which encloses the flow channel Ax. The direction of flow is also indicated in Figures 1A and 1B 25 by the arrow L. The jacket part 11 comprises a collar part 15 at one end of the channel part 14. The collar part comprises a rim 15a, the plane of which is parallel to the longitudinal axis X of the channel. The collar part 15 also comprises a base part 15b, the plane of which is perpendicular to the longitudinal axis X of the channel part 14. On top of the base part 15b is a layer of sealing material 15c.

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The inner surface 14a of the channel part 14 comprises fasteners 16 attached thereto. There are two fastening means 16 and they comprise a hook-like end part 16a by means of which the body parts 17 of the adjusting part 12 are pressed against the layer of sealing material 15c. The fasteners 16 may be of flexible sheet material 35 and may preferably be riveted to the channel portion 14.

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As shown in Fig. 1B, the adjusting part 12 fixed to the sheath part 11 by the fastener 16 is spaced apart from the sheath part 11. The adjusting part 12 comprises two body parts 17. The body part 17 is preferably an L-profile comprising a adjusting part 12 with the X-axis 5 plate part of the sheath part 11 in place. 17a and the associated plate portion 17b at an angle of 90 ° to the associated plate portion 17a. The plate portion 17b is perpendicular to the X-axis.

The adjusting part 12 comprises a first louver part, i.e. a profile part 18a, and a second louver part, i.e. a profile part 18b. In the embodiment of Figures 1A-1B, the slat portion 18b is movable as shown by arrow C in Figure 1B. The louver portion 18b is linearly movable.

In this embodiment of the invention, only the second slat part 18 is movable. Within the scope of the invention, an embodiment is also possible in which the two slat parts can be moved relative to each other.

The position adjusting device 19 of the movable grille part 18b comprises a rod 20 having drive wheels 21 at both ends, preferably tooth-20 wheels. By rotating the rod 20, the drive wheels 21 fixedly connected to the rod 21 are rotated. The rod 20 can be a hexagonal profile rod, in which case it can be turned with a wrench. The drive wheels 21 engage the abutment surface 22 of the movable grille portion 18b. In the most preferred embodiment of the invention, the drive wheel 21 is a gear wheel and the abutment surface 22 is a stop gear 22 cooperating with the gear wheel 21. The rod 20 is intended to act as a synchronizing rod. By means of the rod 20, both ends of the slat part 18b to be moved are moved simultaneously. In this way, the transfer movement is synchronized so that both ends of the slat part are moved the same distance. The flow gap between the louvre parts 18a, 18b then remains the same and in the desired flow cross-sectional area at all valve setpoints.

A flow gap A2 is left between the first grille part 18a and the second grille part 18b. This flow gap narrows with respect to the inlet direction L of the air flow. This flow gap A2 is adjusted by moving the slat part 18b linearly with the position adjusting device 19 as indicated by the arrow c.

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Figure 2 shows in more detail a ventilation valve according to the invention. Figure 2 shows the movable slat part 18b and the means connected thereto for realizing the linear adjustment movement. The position adjusting device 19 comprises a mounting plate 5 23 connected to the plate part 17a of the body part. The plate 23 comprises a hole 24 through which the rod 20 is arranged to pass. At the same time, the mounting plate 23 acts as a bearing point for the rod 20. The ends of the rod 20 are further adapted to pass through a hole 25 in the plate portion 17a of the body 17. The end of the rod 20 comprises a notch 26 into which the end of a tool, e.g. a screwdriver, can be fitted to turn the rod 20 and move the profile 18b.

The jacket part 11 further comprises a notch 27 in the edge part 15a of the collar part 15, through which the tool can be brought into engagement with the rod 20.

By rotating the rod 20, a drive wheel 21 is rotated, which is operatively connected to a abutment surface 22 fixed in the slat 18b, which abutment surface is preferably a straight abutment surface. In the embodiment of Figure 2, the drive wheel 21 is a gear and the abutment surface 22 is a rack. Preferably, said parts are made of plastic.

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The abutment surface 22 further presses against the plate portion 17b of the body 17 and is movable along said straight plate portion. The abutment portion 22 may further comprise a separate plate portion which engages the other side of the plate portion 17b of the body 17 and ensures that the movable slat portion 18b remains attached to the body 17 in all operating conditions.

As shown in Fig. 2, the adjusting part 12 is connected to the body 17 by a fastening member 16. The fastening member 16 presses the body 17 against the sheath part 11.

In the embodiment of the figure, the louver part 18a is in a fixed position in the body 17. The louver part 18a comprises a fastening plate 29 through which a fastener 30, e.g. a rivet, is passed, and which fastener further engages the body 17 with its plate part 17b.

The adjusting device 19 displaces the slat part 18b linearly and the position of the slat part can be read from a scale 28, which is preferably a millimeter-millimeter. In the embodiment shown in Fig. 2, the scale is arranged on the inner surface 14a of the channel part 14.

Fig. 3A is a reduced view of a change-over valve according to the invention, taken mainly along the section line of Fig. I-I. As shown in the figure, the slat part 18b can be moved linearly. The louvre part 18b comprises a straight surface portion 31 controlling the air flow, the plane of which is at an angle α to the central axis X of the flow channel A2 of the ventilation valve. As shown in Fig. 3A, the duct A2 10 converges with respect to the flow direction L of the air flow. In addition, the slat portion 18 comprises a curved flow pre-guide surface 32 associated with the surface portion 31, further connected directly to the flange portion 33, which flange portion 33 is approximately perpendicular to the axis X. The flange part 33 acts as a movable sealing part, allowing the adjustment movement of the profile and allowing the flow of air 15 only between the slats 18b and 18a. Figure 3A shows the operating position of the ventilation valve in which the flow path A2 is at its maximum.

In Fig. 3B, the movable louvre part 18b has been moved to the position implementing the minimum air flow 20, i.e. to the position where the flow cross-sectional area A2 is at a minimum. In Fig. 3B, arrow c shows the movement of the movable profile part 18b to the position of the ventilation valve implementing the minimum air flow.

25 The slats 18a and 18b are similar and therefore only one type of slat parts need be made in production. The louvre parts 18a and 18b are fixed to the structure, respectively, so that the flow-deflecting main surfaces of the louvre parts, i.e. the surface portions 31, are at a corresponding angle to the central axis X of the flow channel A2, α is preferably in the range 3-30. The surface portions 31 are most preferably straight surfaces and then the surface plane is at an angle α to the central axis X of the flow formula A2, then α is in the range of 3-15 ° and most preferably about 7 °.

Figure 4 shows a functional diagram of a ventilation valve according to the invention. According to the invention, the operation diagram is used in Figure 4 as follows. The opening position is read from the scale and measured at the same time

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pressure over the ventilation valve with the pressure connection described below. The volume flow corresponding to the opening position can then be read from the diagram.

Figure 5A shows the preferred arrangement of the scale 28. In the embodiment of Figure 5A, the scale 28 is located on the inner wall 14a of the channel 14. By moving the slat 18b, the opening position at the edge E of the slat part 18b is read.

In the embodiment of Figure 5B, the scale 28 is fitted to the surface of the plate portion 17b of the body 17. By moving the slat part 18b as shown by the arrow c, the opening position can be read at the edge E.

Figure 6A shows an embodiment of the slat 18 in an axonometric view. The slat 18 comprises a hollow interior 34. In this space 34, flow openings open through the openings 35 to transfer the flow pressure to the measuring device. There are several openings 35 near the trailing edge of the flow. They are located linearly in the profile 18 and thus a reliable measurement result and an average over the entire flow path are obtained. The equalizer-20 chamber 34 is further connected 36 to the pressure gauge. The unit 36 is normally plugged and only in the measuring situation is the unit 36 connected to the measuring device.

Figure 6B is a section II-II of Figure 6A. Fig. 6A further shows an embodiment in which the slat 18 comprises an internal space 34 divided by a partition 37. In this case, the space 34a has a pressure connection 38 to the sensor.

Other structures of the slat parts 18 are also possible within the scope of the invention.

30 A sheet metal bent profile part can also be used. In this case, in the pressure measuring event, the pressure is passed directly through the openings 35 to the collector connection 36 and further to the measuring sensor. The equalization chamber is not used in this case.

35 The trailing edges 39 of the slats 18 are rounded. This trailing edge 39 must not be sharp, as it causes turbulence and also too much

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rounding is not desirable as it also causes turbulence. Thus, according to the invention, the ventilation valve comprises a louvre part 18 having a flow-leading surface 32 in front of the flow and an associated second flow-controlling surface 31, preferably a straight surface. According to the invention, the flow gap A2 narrows more sharply at the front flow surface. The slat part according to the invention further comprises a curved trailing edge 39 associated with the flow surface 31 of the middle slat part.

The ventilation valve according to the invention can be mounted on the ceiling or on the wall. The device can also be connected to existing pressure relief boxes. The device according to the invention is quiet even in large volume-flow ranges. There is no resonance. The device is simple to disassemble and therefore it is also easy to clean. The front plate 13 15 of the device is architecturally advantageous.

The ends 40 of the slats 18 comprise a seal, thereby eliminating variations in longitudinal dimensional or installation tolerances. In the structure according to the invention, the openings 35 are arranged in the zone of the maximum speed of the flow no-20, so that the pressure is at a maximum and fouling is unlikely.

The ventilation valve according to the invention functions both as a ventilation valve and as an air flow control part. According to the invention, the following advantages are achieved with the converging duct and in particular the convergence with respect to the direction of flow of the air flow. The velocity of the air increases and at the same time, due to the surface friction between the air flow and the surface of the slat, a sufficient static duct pressure is achieved for the measurement. Thus, in order to achieve a reliable measurement of the static pressure of the air flow 30, the adjustment can be performed on the device and at the same time the measurement of the air flow rate already from the room space. Therefore, no separate adjusting part is required.

A ventilation valve suitable as an exhaust air device has been described above. Thus, through said ventilation valve, in the embodiments shown in Figs. 35 above, air is sucked out of the room space. Within the scope of the invention, an embodiment is also possible in which the air

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the diverter valve is used as the supply air device. In this embodiment, the slats are located relative to each other so that the flow gap between the slats narrows again with respect to the direction of air flow. In this embodiment, the front cover plate 13 is located after the flow gap 5 which narrows with respect to the direction of air flow.

Claims (8)

A vent valve (10) comprising a first damper portion (18a) and a second damper portion (18b), from which it is possible to move the second damper portion (18b) to reduce the flow gap (A2) between the damper portions (18a, 18b). or to increase it, and in which the vent valve (10) the damper portions (18a, 18b) form an elongate gap (A2), whose flow cross-section tapers relative to the flow direction (L) of the current, which vent valve includes takes arrangement by means of which one of the damper parts (18b) of the vent valve (10) can be moved linearly to reduce or increase the flow heel (A2) and which vent valve (10) comprises a control device (19) comprising a drive wheel (21). ) which is coupled to the locking surface (22) of the damper portion (18b) which can be moved, whereby by moving the drive wheel (21) the movable damper portion (18b) is linearly moved, known The ventilation valve (10) comprises a control part (12) which can be releasably fastened in the casing part (11) of the ventilation valve (10) and that there are at least two body parts (17) in the control part (12), between which the damper part (18a , 18b) are connected, the body portion (17) comprising a disc portion (17b) perpendicular to the longitudinal axis (X) of the duct portion (14) of the vent valve (10), along which the locking surface (22) of the drive wheel (21) of the movable damper part (18b) is arranged to slide and the vent valve (10) includes drive wheels (21) and locking surfaces (22) at both ends of the movable control part (18b), the damper part (18b) being movable linearly while the movement of the damper portion (18b) is directed evenly toward both ends of the damper portion (18b). Ventilation valve according to claim 1, characterized in that the drive wheel (21) is a gear and the locking part (22) is a locking tooth. Ventilation valve according to Claim 1 or 2, characterized in that the ventilation valve comprises a closure (20) which, in accordance with Figs. 3, 1, includes similar operating devices at both ends to move the movable damper part (18b) in the desired manner. bearing. Ventilation valve according to any of the preceding claims, characterized in that the bar (20) preferably comprises means for cutting and / or hexagonal profile for moving the bar (20) and the damper part (18b). Ventilation valve according to any one of the preceding claims, characterized in that the ventilation valve comprises such a longitudinal gap (Az) formed between the damper parts (18a, 18b), the starting part of which tapers off steeper than the end part. Ventilation valve according to any of the preceding claims, characterized in that the ventilation valve comprises a front cover part (13) removing the damper parts (18a, 18b), through which or by tangent of which the air flow escapes to the flow gap (A2) between the damper parts. (18a, 18b). Ventilation valve according to any of the preceding claims, characterized in that the ventilation valve comprises a scale (28), advantageously a millimeter scale, the opening position of the functional device being read from the edge (E) of the movable damper part (18b). 25 Ventilation valve according to claim 1, characterized in that both the first damper part (18a) and the second damper part (18b) can be moved linearly in relation to the body (17). 30