BE1023420A1 - Ventilation system with measuring system. - Google Patents

Abstract

A ventilation system comprises a central housing (6) with at least one nozzle (5), an active fan (7) in the housing and a flow control for controlling an air flow through the nozzle, which flow control comprises at least one measuring system (9) for measuring a characteristic of the air, as well as a control system for controlling the air flow on the basis of a characteristic of the air measured by the measuring system (9). Within the central housing (6) a carrier (10) is connected to at least one nozzle (5) which comprises at least the measuring system (9).

Description

Ventilation system with measuring system

The invention relates to a ventilation system comprising a central housing with at least one nozzle, an active fan in the housing and a flow control for controlling an air flow through the nozzle, which flow control comprises at least one measuring system for measuring a characteristic of the air, wherein within the central housing at least one nozzle a carrier is connected which comprises at least the measuring system, which housing is provided with a receiving space for the carrier positioned in the path of the air flow, in which receiving space the carrier can be received, or from which receiving space the carrier is removable by shifting transversely to that path of the air flow.

Such a ventilation system is known. It can be used, for example, for the central extraction of air from the various rooms in a building. Depending on the nature of the use of the rooms and the number of people in them, the level of extraction can be set separately for each room. To this end, for example, a flow controller located in the relevant channel through which that space is connected to the fan can be controlled in the desired manner by the control system.

Parameters that can play a role in this are the CO2 content, the humidity, temperature and the like. For example, if there are a large number of people in a particular room, the CO2 content may reach undesirable levels. The increase in the CO2 content is observed by the relevant sensor of the measuring system, such that the software of the control system can set the flow controller to a higher flow. According to another example, the humidity of the air extracted from a wet cell can give rise to an increase in the flow rate. As soon as a decrease in the relevant parameter is observed, the flow can be reduced.

Although the aforementioned has been given as an example for extracting air from the rooms concerned, it is also conceivable with such a ventilation installation to supply air via the flow controllers to the rooms concerned. It is also possible to provide double channels with which on the one hand air can be supplied to a specific space and on the other hand air can be discharged therefrom under the influence of the fan.

Such a ventilation system is known from NL-C-1038209, wherein pipe-shaped control units are mounted on the nozzles on the outside of the central housing, in which a valve with drive and measuring unit is included. Connection cables that are routed from the respective control units to and in the central housing ensure a connection with the central control system that is located in the housing.

The disadvantage of this known ventilation system is that the subsequent installation of a control unit and the measuring unit, or the replacement thereof, is difficult. To that end, the line connected to the relevant nozzle must be detached and possibly shortened. Due to space saving, the ventilation systems are often placed in a limited space, which causes problems when performing these activities. A further disadvantage is that the connections, in particular the cables between the flow regulator and the control system, run outside the central housing, whereby the space used is increased and the vulnerability of the verification system increases.

The object of the invention is therefore to provide a ventilation system of the type described above which does not have these disadvantages and which is easier and more reliable to handle during installation and in use. This object is achieved in that the receiving space is limited by a bearing wall with at least one bearing edge and in that the bearing is provided with a support element which cooperates with the bearing wall. Although the carrier can be supported in different ways relative to the carrier wall. such as by a screw connection, by gluing and the like, preference is given to a support element, preferably in the form of a hook that is hooked over the support edge of the support wall.

The unit or carrier with the measuring system is now not located on the outside of the mouthpiece, but is pushed or inserted into the housing itself. This means that the unit can be installed or replaced without the need to disconnect or adjust the pipe connection to the relevant nozzle.

Another important advantage is that the external dimensions of the ventilation system and the pipes connected to it are not dependent on the presence or absence of the measuring system. The use of space is therefore well determined and limited. The connections and cables for the various functions of the measuring system are also included entirely within the central housing, so that reliability is favorably influenced. Furthermore, the ventilation system according to the invention has the advantage that the exterior thereof looks better and is less susceptible to contamination, because the messy impression that the various cables make is removed since they are now hidden from view under the cover.

The carrier is preferably located at the mouth of the mouthpiece in the central housing at a distance from the free end of the mouthpiece. Unlike the known ventilation system, the nozzles remain free of additional elements, so that the pipes in question can be unambiguously connected without having to take the measuring systems into account. The carrier with the measuring system is also well protected against external influences in the interior of the central housing, which improves the service life and reliability.

The carrier can be provided with relatively small openings or leakage current openings, via which air from the line can reach the relevant sensor. The flow control may comprise means for controlling a control system for controlling the air flow on the basis of a property of the air measured by the measuring system. That control system can for instance be located in the channels connected to the housing of the ventilation system. Such a control system may optionally be located within the housing.

For example, the measuring system may comprise a sensor unit for measuring a characteristic of the air, such as the CO2 content, the air humidity and the like, which sensor unit outputs a signal which is a measure of that characteristic and is connected to the control system. According to a simple embodiment, the sensor unit may comprise a sensor with integrated electronics for issuing a measurement signal, such as a sensor integrated on a printed circuit board.

As already mentioned, the carrier can be well protected in the interior of the central housing. In that connection, the central housing is preferably provided with a circumferential circumferential wall with circumferential edges facing away from each other, between which the at least one nozzle is situated, the supporting wall and possibly supporting edge then being formed by one of the circumferential walls or circumferential edges, respectively. Alternatively, a separate bearing wall can be arranged within the circumferential wall, in which case the bearing edge of said separate bearing wall is parallel to one of the circumferential edges. The receiving space is then formed between the separate supporting wall and the peripheral wall, and a cover can also be arranged on one of the peripheral edges, which cover covers the inner space of the central housing.

The various components of the ventilation system, in particular the fan, the carriers and measuring units and the flow control can be placed in a simple manner at their predetermined positions in the central housing. After the electrical connections have been made between these components, for example via a bus system known per se, the whole can be hermetically sealed by placing the cover on the peripheral wall. The circumferential wall can, for example, be permanently closed off at the edge opposite the cover by a molded-on bottom.

In the central housing, there is preferably an intermediate wall between the two peripheral edges. in which intermediate wall there can be at least one mouth in which the carrier is accommodated, preferably by sliding inwards into the mouth. The carrier can thus be stably arranged in the housing, and a cover can also be arranged on one of the peripheral edges, which cover covers the inner space of the central housing. The mouth, which belongs to a receiving space, through which mouth, as stated, the carrier can be inserted into the guide, is preferably turned towards the peripheral edge on which the cover is situated, such that the cover also covers the guide and any support received therein.

In connection with a stable attachment of the carrier, it can have a stop at a distance from the hook. In that case the bearing wall can have a recess at a distance from the bearing edge such that with a hook resting against the bearing edge. the stop is in the recess to prevent the carrier from coming off the carrier wall. By means of such a click system the carrier can be reliably placed, and possibly also removed.

The carrier may comprise a sensor hu in which a sensor, preferably an integrated circuit with sensor, is included. The sensor housing preferably comprises coupling means for coupling a further carrier to the sensor housing. A compact unit can thus be formed by means of which various properties of the air can be measured, such as CO2 content and humidity. Furthermore, this possibility of coupling the sensor housings has the advantage that various combinations of sensors can be made in a simple manner, without it being necessary to make a print each time with the desired sensors and associated electronic components thereon. A number of basic prints will suffice, which can then be combined in the desired manner by clicking the sensor housings together. For this purpose, in one embodiment, the sensor housing can be provided with coupling means for coupling a further carrier to the sensor housing.

In a further embodiment, the sensor housing comprises two sides facing away from each other, which sides are transversely oriented to the mouthpiece, and one side facing the mouthpiece, the side facing the mouthpiece having smaller dimensions than the mouthpiece, so that in use an air flow through the nozzle flows along the sides of the sensor housing remote from each other.

In one embodiment, the sensor housing and the support element each have a longitudinal direction, the length direction of the support element being transverse to the length direction of the sensor housing. so that the carrier has an L or 1-shaped top view. Because the longitudinal directions of the sensor housing and the support element are transverse to each other, an L- or T-shaped top view of the carrier is created.

Preferably, the sensor housing and the support element each have a longitudinal direction, wherein the length direction of the support element is parallel to the bearing edge, and the length direction of the sensor housing is directed transversely to the length direction of the support element.

Of course, a plurality of nozzles can be provided, each with a respective guide for receiving the carrier. The ventilation system can be operated in various ways. According to a first possibility, the fan can be adapted to suck in air via at least one nozzle and the central housing comprises an outlet for discharging the air drawn in via the at least one nozzle. According to a second possibility, the fan can be arranged for supplying air via at least one nozzle and the housing can comprise a supply for supplying the air discharged via the at least one nozzle. The combination of supply and removal of air is also possible.

The invention also relates to a carrier for a ventilation system as described above, comprising a sensor housing, a connecting element connected to the sensor housing, such as a hook. and at least one measuring system for measuring an air property. A stop can be provided at a distance from the hook and on the open side of the hook for stabilizing the carrier with respect to a supporting wall. In addition, coupling means can be provided for coupling a further carrier. In particular, the carriers can be provided with identical coupling means, such that the carriers themselves are identical, with the exception of the measuring system included therein.

In one embodiment, the support element and the sensor housing are oriented relative to each other such that the carrier has an L or T-shaped top view. The L or T shape is preferably obtained in that the sensor housing and the support element each have a longitudinal direction, wherein the length direction of the support element is directed transversely to the length direction of the sensor housing. Because the longitudinal directions of the sensor housing and the support element are transverse to each other, an L- or f-shaped top view of the carrier is created.

In addition, the invention relates to a building comprising at least one space, a ventilation system as described above, as well as channels that each extend between the at least one space and a nozzle of the housing. The flow control can herein have a control system for controlling the air flow on the basis of a property of the air measured by the measuring system. This control system can for instance be designed as a control valve which is located in a channel and / or in a valve.

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the figures.

Figure 1 shows a schematic view of an embodiment of the ventilation system according to the invention.

Figure 2 shows a variant of the housing of the ventilation system.

Figures 3 and 4 show two combined carriers.

Figure 5 shows an exploded carrier.

Figure 6 shows a side view of the housing.

The ventilation system shown in Figure 1 is located in a building, in particular a dwelling 1. which comprises several rooms 2, 2 \ .... The ventilation system can be designed for extracting air from the rooms, for supplying air thereto or for both supplying and discharging air. In the latter case, two channels are provided per departure. In the exemplary embodiment shown, each room 2, 2 ', .. is provided with a single channel 3, 3', .. which flows into the room concerned via a valve 4, 4 \ .. The channels 3, 3 ... are all connected to a nozzle 5, 5 ". ... of the central housing 6. An active fan 7 is present in this central housing in a known manner, which ensures that air is sucked from the channels, or that air is delivered to the channels. The air extracted from the rooms can be led out via the outlet 8. The channels 3 or the valves 4 can have a control system 33 which is connected to the flow control of the ventilation system, to influence the air flow. However, such control systems are not necessary. It is also possible to influence the air flow by changing the speed of the active fan 7.

Figure 2 shows the ventilation system with housing 6 with slightly raised cover 17. The housing 6 comprises four side walls 12 with two nozzles 5 or a nozzle 5 and the outlet 24. In the interior of the housing 6 there is an intermediate wall 30. with thereon an active fan 7 is included. Adjacent to the side walls 12, the mouths 29 of the receiving spaces 11 are provided in the intermediate wall 30 in the interior of the housing 6. The carriers 10 are accommodated in the accommodation spaces 11. The receiving space 11 adjoins the side wall 12. This allows the air flow along the carrier 10 to be supplied or discharged, their side of the carrier facing the mouthpiece and another side of the carrier 10 facing the interior of the housing 6 . The carrier 10 further comprises two sides which are remote from each other and which are directed transversely to the nozzle 5. The air stream which is supplied or discharged along the carrier will flow along these mutually remote sides of the carrier 10. The housing 6 further comprises a bottom part 15. The carrier 10 is provided with connecting elements 14 for connecting the carrier 10 with a control system via cables 13. See figures 3-5. The cover 17 is provided for placement on the upper edges 16 of the housing. side walls 12. This cover covers the interior of the housing 6, so that the active fan 7 and the carriers 10 are protected against external influences.

Figures 3-5 show an embodiment of a carrier 10 with a sensor housing 25 with support elements in the form of hooks 20 for supporting the carrier 10 on the carrier edge 18 of the carrier wall 19 (see Figure 2) which together with the circumferential wall 16 receiving space 11. In this support wall there is an opening 32 which is aligned with respect to the associated nozzle 5. The support has a stop 31 at a distance from the hook 20, such that with the hook resting on the support edge 18, the stop 31 is properly snapped into the opening 32 in the carrier wall 19, which opening 32 is aligned with respect to the associated nozzle 5. Figure 3 shows a reference axis system for indicating orientation of the dimension directions of the sensor housing and the support element relative to each other. The longitudinal direction of the sensor housing 25 is oriented in the x-direction, the longitudinal direction of the hook 20 is oriented in the y-direction and thus is perpendicular to each other. The hook 20 is provided at a free end of the support element. In order to obtain a stable support for the carrier, the hook 20 extends in a longitudinal direction y. The longitudinal direction y of the hook 20 is perpendicular to the longitudinal direction x of the sensor housing 25. When the carrier 10 is placed in the receiving space 11, the longitudinal direction y of the hook is parallel to the bearing edge 18. The stop 31 is at a distance of the hook 20 and of the sensor housing 25. As a result, the carrier has a T-shaped top view (not shown), wherein the hook 20, the crossbar and the sensor housing 25 form the stem of the T.

In the exemplary embodiment shown, the sensor housing 25 consists of two halves 22. 23 which are clicked on each other and which enclose the measuring system 9, wherein leakage openings are provided for entering the air: on the half 22 the hook 20 is formed. Half 22 of the sensor housing 25 and the hook 20 are oriented relative to each other such that a T-shaped top view is obtained. Furthermore, the sensor housing comprises male fastening means 26 and a female fastening means 27 which are positioned such that two sensor housings can be snapped against each other as shown in figures 3 and 4. The cables are connected to the connecting elements 14 by means of cables 13. connected to the connecting elements 14. associated measuring system 9.

Figure 6 shows that optionally a single carrier 10 with measuring system can be placed at the height of a nozzle 5, or two (or more) carriers 10 coupled to each other, each with its own measuring system. Furthermore, it is shown in Figure 6 that the side of the sensor housing 25 facing the nozzle 5 has smaller dimensions than the nozzle 5, so that the air flow can be supplied or discharged along two sides of the sensor housing 25 facing away from each other. It is preferred that in the case of two or more connected carriers 10 the total width dimension is smaller than that of the nozzle, so that the air flow can be supplied or discharged along free sides of the coupled carriers.

It is not necessary to attach a carrier 10 to each nozzle 5. It is also not necessary to connect each nozzle 5 to a channel 3. In such a case, the relevant nozzle 5 can be closed by a cap 34, see figure 5.

List of reference signs 1. Home 33. Control system 2. Departure 34. Rap 3. Channel 4. Valve 5. Nozzle 6. Central housing 7. Active fan 8. Drain 9. Measuring system 10. Carrier 1 1. Reception space 12. Side wall 13. Cable 14. Connection element 15. Bottom part 16. Side wall edge 17. Cover 18. Supporting edge 19. Supporting wall 20. Hook. support element 21. Motor 22. Half of sensor housing 23. Half of sensor housing 24. Exhaust 25. Sensor housing 26. Male fastener 27. Female fastener 28. Stopper 29. Mouth guide 30. Intermediate wall 3 1. Recess 32. Opening

Claims (24)

Conclusions A ventilation system, comprising a central housing (6) with at least one nozzle (5), an active fan (7) in the housing and a flow control for controlling an air flow through the nozzle, which flow control comprises at least one measuring system (9) ) for measuring a characteristic of the air, wherein within the central housing (6) a carrier (10) is connected to at least one nozzle (5) which comprises at least the measuring system (9), which housing (6) is provided with a receiving space (11) for the carrier (10) positioned in the path of the air flow, in which receiving space the carrier can be received, or from which receiving space the carrier can be removed, by sliding transversely with respect to that path of the air flow, characterized in that the receiving space (11) is bounded by a support wall (16. 19), such as with at least one support edge (18), and in that the support (10) is provided with a support element which is supported with respect to the support wall (16, 19), such as a hook (20) hooked over the support edge (18) of the support wall (16, 19). Ventilation system according to claim 1, wherein the carrier (10) is located at the mouth of the mouthpiece (5) in the central housing (6) at a distance from the free end of the mouthpiece. Ventilation system according to one of the preceding claims, wherein the flow control is provided with means for controlling an air flow control system (33) based on a property of the air measured by the measuring system (9). Ventilation system according to any one of the preceding claims, wherein the central housing (6) is provided with a circumferential circumferential wall (12) with circumferential edges (16) facing away from each other, between which the at least one nozzle (5) is situated, and the supporting edge (18) of the supporting wall (19) is parallel to one of the peripheral edges (16). Ventilation system according to one of the preceding eelelusions, wherein the central housing (6) is provided with a circumferential circumferential wall (12) with circumferential edges (16) facing away from each other, between which the at least one nozzle (5) is situated, and the supporting edge is formed by one of the peripheral edges (16). Ventilation system according to claim 4 or 5, wherein the central housing is provided with an intermediate wall (30) spaced between both peripheral edges and directed transversely to the peripheral wall (12). in which intermediate wall (30) there is at least one mouth (29) in which the receiving space (11) and the carrier (10) are accommodated. A ventilation system according to any one of the preceding claims, wherein the central housing (6) is provided with a bottom (15) on one of the peripheral edges (16) of the peripheral wall (12). A ventilation system according to any one of the preceding claims, wherein the central housing (6) is provided with a cover (17) on one of the peripheral edges (16) of the peripheral wall (12), which cover covers the inner space of the central housing. Ventilation system according to claims 6 and 8 or 7 and 8, wherein the mouth (29) of a receiving space (11) faces the pull-in edge (16) on which the cover (17) is located such that the cover also accommodates the receiving space (11) ) and any carrier (10) included therein. 10. Ventilation system as claimed in any of the foregoing loops, wherein the measuring system comprises a sensor unit for measuring a property of the air, such as the CO2 content, the air humidity and the like, which sensor unit emits a signal which is a measure of that property and is connected. with the control system. The ventilation system of claim 10, wherein the sensor unit comprises a sensor with integrated electronics for outputting a measurement signal, such as a sensor integrated on a printed circuit board. A ventilation system according to any one of the preceding claims, wherein the carrier (10) is provided with a stop (28) remote from the hook (20), and the carrier wall (16, 19) is provided with a recess (31) of the bearing edge (18) such that with a hook resting against the bearing edge, the stop is in the recess for preventing the carrier from coming loose from the bearing wall. A ventilation system according to any one of the preceding claims, wherein the carrier (10) comprises a sensor housing (25) in which a sensor, preferably an integrated circuit with sensor, is included. Ventilation system according to claim 13, wherein the sensor housing (25) has coupling means (26, 27) for coupling a further carrier to the sensor housing. A ventilation system according to any one of the preceding claims, wherein a plurality of nozzles (5) are provided, each with a respective receiving rack (11) for receiving the carrier (10). A ventilation system according to any one of the preceding claims, wherein the fan (7) is adapted to suck in air via at least one nozzle (5) and the central housing (6) comprises an outlet (24) for discharging the air drawn in at least one nozzle, and / or wherein the fan is adapted to supply air via at least one nozzle and the housing comprises a supply for supplying the air discharged via the at least one nozzle. A carrier (10) for a ventilation system according to any one of the preceding claims, comprising a sensor housing (25). a support element connected to the sensor housing, such as a hook (20) and at least one measuring system (9) for measuring a property of air. A support according to claim 17, wherein the support element and the sensor housing are oriented relative to each other such that the support has a T-shaped top view. Carrier (10) according to claim 17 or 18, wherein a stop (31) is located at a distance from the hook (20) and on the open side of the hook. A carrier (10) as claimed in any one of claims 17-19, wherein coupling means (26, 27) are provided for coupling a further carrier. A combination, two carriers (10) according to claim 20, wherein the carriers are provided with identical coupling means (26, 27). A building comprising at least one room, a ventilation system according to any one of claims 1-16, comprising a central housing (6) with at least one nozzle (5), an active fan (7) in the housing and a flow control for controlling of an air flow through the nozzle comprising flow control at least a measuring system (9) for measuring a characteristic of the air, wherein a carrier (10) is connected to at least one nozzle (5) within at least one nozzle (5) within the central housing (6) the measuring system (9), which housing (6) is provided with a receiving space (11) for the carrier (10) positioned in the path of the air flow, in which receiving space the carrier can be received, or from which receiving space the carrier can be removed , by shifting transversely to that path of the air flow, wherein the receiving space (11) is bounded by a support wall (16, 19), such as with at least one support edge (18), and that the support (10) is provided and a supporting element which is supported with respect to the supporting wall (16. 19). such as a hook (20) that is hooked over the bearing edge (18) of the bearing wall (16. 19). and channels (3, 3 ...) each extending between the at least one space and a mouthpiece (5) of the housing. The building of claim 22. wherein the flow control comprises a control system (33) for controlling the air flow based on a property of the air measured by the measuring system (9). The building of claim 23, wherein the control system (33), such as a control valve, is located in a channel (3. 3 "...) and / or in a valve (4, 4", ..).