NL2014563B1 - Ventilation installation with adjustable manifold and manifold therefor. - Google Patents

Abstract

A ventilation installation for supplying and / or discharging air in a building (4) which has several rooms (5, 5 ', 6, 6') has a blower (14) for generating an air flow, a main channel (12, 13), a manifold (10, 11) with a main connection (19) and several auxiliary connections (20). There are also several auxiliary channels (7, 7 ', 8, 8') as well as several valves (9). The main channel (12, 13) is connected to the blower (14) and to the main connection (19) of the manifold (10, 11). The auxiliary channels (7, 7 ', 8, 8') are connected to one of the auxiliary connections (20) of the manifold and to the valves (9). The manifold (10, 11) consists of a plurality of manifold parts (16, 17) and has coupling means (18) by means of which the manifold parts are mutually coupled. To simplify the connection of the channels, the coupling means (18) can couple the manifold parts (16, 17) in different mutual positions.

Description

Ventilation installation with adjustable manifold. and manifold therefor

The invention relates to a ventilation installation for supplying and / or discharging air in a building that has several rooms, comprising a blower for generating an air flow, a main duct, a manifold with a main connection and several auxiliary connections, several auxiliary channels and several auxiliary channels as well as several valves for an associated space, wherein the main channel is connected to the booster and to the main connection of the manifold, one of the auxiliary channels is connected to one of the auxiliary connections of the manifold and another auxiliary channel is connected to another of the auxiliary connections of the manifold, and one of the valves is connected to one of said auxiliary channels and another valve is connected to another of said auxiliary channels, which manifold comprises several manifold parts and coupling means by means of which the manifold parts are mutually coupled.

Such a ventilation installation is known from FR-A-2965334. A modular manifold has been used which, depending on the number of spaces to be operated, can be equipped with more or fewer modules. By means of this known modular manifold, air can be supplied to or discharged from the relevant spaces. It can also be hot or cold air. The air is usually transported through channels in the form of tubes with a certain diameter. Such tubes take up a relatively large amount of space, and especially when assembled at the manifold, they can provide a complicated tube system that takes up a lot of space. After all, the tubes arrive at the manifold from different directions, and therefore cannot always be connected in a more or less direct line. This can lead to problems especially with manifolds with a relatively large number of manifold modules.

The object of the invention is therefore to provide a ventilation installation in which the various tubes can be connected to the manifold in a more rational way. A further object is to provide a ventilation installation in which the various tubes can be connected to the manifold with the smallest possible amount of space. These and other objectives are achieved in that the coupling means are designed for coupling the manifold parts together in different mutual positions.

Thanks to the possibility of placing the manifold parts in different mutual positions, it is not necessary to lay the pipes to be connected to those manifold parts in all kinds of bends. As a result, the main connection and the auxiliary connections can be placed in the most suitable direction with respect to the incoming pipes. This greatly simplifies the connection between those connections and the tubes, while also taking up space as the tubes do not have to be bent as strongly.

In particular, the manifold may comprise a main manifold part which is provided with the main connection and at least one auxiliary manifold part which is provided with one or more auxiliary connections. A single auxiliary manifold part can be provided that contains all auxiliary connections, but it is also possible to provide several auxiliary manifold parts, each with one or more auxiliary connections.

The coupling means can be provided between the main manifold part and an auxiliary manifold part. In addition or alternatively, coupling means may be provided between two or more auxiliary manifold parts.

The manifold can be made in all shapes and sizes. Preference is given to an embodiment in which the manifold has a polygonal cross-section and the manifold parts are offset in the longitudinal direction (transversely to the cross-section) of the manifold, wherein the coupling means are situated on or near to each other transverse surfaces of neighboring adjacent manifold parts. The number of mutually different positions in which the manifold parts can be coupled to each other can in that case be equal to the number of corners or sides of the polygonal cross-section of the manifold.

The coupling means can be designed in different ways, and can for instance comprise clamps that are clamped on the various manifold parts. Preferably, however, the coupling means comprise threaded means. The pitch of these screw means can be selected such that the connection is established by a stroke with a size whose magnitude relative to a full circle is the inverse of the number of possible mutual positions of the respective adjacent manifold parts.

Preferably, all manifold parts have a through-going chamber part that opens at opposite ends of the manifold part, which chamber parts connect to each other and together form the internal chamber of the manifold, and closing lids are provided at opposite ends of the chamber at the extreme manifold parts. At least one of the auxiliary connections can also be closed by a closing cover.

The main connection and the auxiliary connection can all be permanently opened, such that a continuous and unchangeable flow always occurs through the manifold. however, alternatively, it is also possible to control one, several or all connections. To this end, in an alternative embodiment, at least one of the auxiliary connections may be provided with a flow regulator, such as a flow control valve, for controlling the air flow through that connection. This may involve an individual control per auxiliary connection, so that the respective rooms connected thereto can also be operated individually. The demand can, for example, be controlled manually by a setting controller in the relevant room.

However, it is also possible to let the flow regulator function automatically, based on one or more characteristics of the air. To this end, at least one measuring system can be provided for measuring a characteristic of the air at the flow controller and a control system for controlling the flow controller on the basis of the characteristic of the air measured by the measuring system. When extracting air from the various rooms, the measuring system can measure the composition of the extracted air per room, and on the basis of that measurement the flow regulator can be opened further or less by means of the control system.

In a compact, efficient embodiment, the flow controller, the measurement system and the control system can be included in a cassette. At least one of the manifold parts is provided with a cassette chamber in which the cassette is accommodated. To simplify the installation of such a cassette, the cassette chamber can have a guide by means of which the cassette can be guided in the cassette chamber or out of the cassette chamber. This also makes it possible to easily insert, remove or replace a cassette afterwards.

In particular, the guide of the cassette chamber can open onto the exterior of a manifold part and there is closed off by a guide cover. If several adjacent manifold parts have a cassette chamber, these cassette chambers can be closed by a common cover. Also included under that cover are the electrical leads required for signal transmission, power supply and the like. In this way, a well-protected, reliable unit is obtained that is easy to install and maintain.

The application of the manifold in an individual home has been described in the foregoing. However, it is also possible to use the manifold in a collective residential building. The booster is centrally positioned in such a building, while the ventilation per home is then controlled by the manifold provided with valves.

An office building is also eligible as an application example for the manifold.

The invention also relates to a manifold for a ventilation device as described above, comprising a plurality of manifold parts as well as coupling means by means of which the manifold parts are mutually coupled, and characterized in that coupling means are designed for coupling the manifold parts to each other in different mutual positions.

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

Figure 1 shows a section through a house with a ventilation installation according to the invention.

Figures 2a-e show different variants of a manifold.

Figure 3 shows a further variant of a manifold.

Figures 4a-d show different embodiments of a manifold with a blower.

Figure 1 shows a cross-section of a house 4 consisting of different floors 1, 2 and in this case an attic 3. The floors 1, 2 have several rooms or spaces 5, 5 ', 6, 6' on which an auxiliary channel is each 7, 7 ', 8, 8' is connected. These auxiliary channels all open into so-called valves 9 which determine the outflow opening of the auxiliary channels in the various spaces. In the exemplary embodiment shown, the auxiliary channels 7, 7 'from the lower floor 1 are all connected to a first manifold 10, while the auxiliary channels 8, 8' from the upper floor 2 are connected to a second manifold 11. Both manifolds 10, 11 are connected via a main channel 12 and 13 respectively connected to the blower 14, which has an outlet 15 via which the air extracted from the various spaces is discharged.

Although in the embodiment shown a variant is shown in which the air is extracted from the room, it is also possible to reverse the air flow and to supply air to the rooms with the relevant ventilation installation. It is also possible to arrange both variants in one and the same house, the installation being designed in duplicate for, on the one hand, supplying air to the various spaces, and, on the other hand, for discharging air from the various spaces.

Various possible variants of the manifold 10, 11 are further shown in figures 2a-e and 3. In particular, Figure 2e shows that the manifold 10, 11 consists of a main manifold part 16 and an auxiliary manifold part 17. These manifold parts 16, 17 have threaded means 18 on their faces facing each other, by means of which they can be coupled to each other. The manifold 10, 11 has a main connection 19 to which the main channels 12, 13 shown in Figure 1 can be connected, and a plurality of auxiliary connections 20 to which the auxiliary channels 7, 8 can be connected. As shown in Fig. 2e, an interior chamber 30 is provided in the interior of these manifold parts 16, 17, through which the main connection 19 and the auxiliary closures 20 are connected to each other.

In the exemplary embodiment shown, the manifold 10,11 is square, which means that the manifold parts 16,17 can be coupled to each other in four different ways. Figure 2e, for example, shows that the main connection 19 is oriented perpendicularly upwards to the auxiliary connections 20. In the example of Figure 2b, all connections 19, 20 are oriented in the same direction, in Figure 2a, the main connection 19 is opposed to the auxiliary connections 20 and in Figure 2d, the main connection 19 is directed perpendicularly downwards with respect to the auxiliary connections 20. Figure 2c shows the embodiment of Figure 2e in the assembled state.

The coupling means 18 may comprise threaded means with a pitch such that the connection between the main manifold part 16 and the auxiliary manifold part 17 can be established by a quarter turn, namely from four different starting positions to obtain the different possibilities shown in Figure 2. These coupling possibilities are useful when connecting the auxiliary channels 8, 9 and the main channel 12, 13 arriving from different directions, in such a way that it is usually possible to work without undesired bends.

It should be noted that the auxiliary manifold part 17 can also consist of several parts, each with a single auxiliary connection 20, and which can be positioned in different ways relative to each other in the same way as the orientations of the main manifold part 16 relative to the total auxiliary manifold part 17 as shown. in Figure 2a-e. Coupling means 18 also occur on the faces of each other of that auxiliary manifold part 17 consisting of different parts. The ends of both the main manifold part 16 and the auxiliary manifold part 17 have a closing cover 21 at one end remote from the coupling means 18.

In the embodiment of the manifold 10,11 as shown in Figure 3, a cassette 22 is included with each auxiliary connection 20 in the auxiliary manifold part 17. To this end, the auxiliary manifold part 17 has a cassette chamber 23 at the level of each auxiliary connection 20, in which the cassette 22 can be removed or received by sliding up and down. Each cassette 22 has a flow regulator 24 designed as a butterfly valve, a motor 25 and a sensor unit 29 which can measure, for example, the air humidity, the carbon dioxide content and the like. The various cables intended for supplying the motor 25 and for signal transmission are not shown in the exemplary embodiment shown, but can be laid along the outside of the auxiliary manifold part 17 and under the cover 28 to be discussed.

The cassette chamber 23 has a guide 26 which is directed transversely to the direction of the air flow occurring through the auxiliary connections 20, such that the cassettes 22 are positioned in the desired manner and in the correct position with respect to that air flow through the auxiliary connections 20 can become. The cassette chamber 23 has a mouth 27 which can be closed by the aforementioned cover 28. In the illustrated embodiment of Figure 3, only a single cover 28 is required, because all the mouths 27 point upwards in the same way and can thus be closed together. If the auxiliary manifold part 17, as already mentioned above, consists of separate parts that can each be connected to each other with different orientations, each cassette chamber 23 will be closed by its own cover.

Figures 4a-d show various combinations of the manifold 10, 11 with the blower 14. In the example of Figures 4a and 4c, the main connection 19 is thereby turned away from all auxiliary connections 20; in the example of Figs. 4b, d, the main connection is mounted at the longitudinal extreme end of the manifold 10,11, the lid 21 as shown in Fig. 3 being removed from the end of the main manifold part 16 and instead thereof is connected to the main connection 19. In the foregoing there is a booster 14, but for this purpose another installation can be used such as a heat exchanger.

List of reference signs 1. Lower floor 2. Upper floor 3. Attic 4. Dwelling 5. 5 '. Space downstairs 6., 6. Space upstairs 7., 7 ". Auxiliary channel ground floor 8, 8 ". Auxiliary channel upper floor 9. Valve 10. First manifold 11. Second manifold 12. Main channel 13. Main channel 14. Blower 15. Exhaust 16. Main manifold part 17. Auxiliary manifold part 18. Coupling means 19. Main connection 20. Auxiliary connection 21. Closing cover 22. Cassette 23. Cassette room 24. Valve 25. Drive motor valve 26. Cassette chamber guide 27. Cassette chamber outlet 28. Lid 29. Sensor unit 30. Chamber

Claims (18)

A ventilation installation for supplying and / or discharging air in a building (4) which has a plurality of rooms (5, 5 ', 6, 6'), comprising a blower (14) for generating an air flow, a main channel (12, 13), a manifold (10, 11) with a main connection (19) and several auxiliary connections (20), several auxiliary channels (7, 7 ', 8, 8') and several valves (9) for an associated space , wherein the main channel (12, 13) is connected to the blower (14) and to the main connection (19) of the manifold (10, 11), one of the auxiliary channels (7, 7 ', 8, 8') is connected to one of the auxiliary connections (20) of the manifold and another auxiliary channel is connected to another of the auxiliary connections (20) of the manifold, and one of the valves (9) is connected to one of the auxiliary channels (7, 7 ', 8, 8' ) and another valve is connected to another of the auxiliary channels, which manifold (10, 11) comprises a plurality of manifold parts (16, 17) and coupling means (18) by means of which the manifold parts are mutually coupled, characterized in that coupling means (18) are designed for coupling the manifold parts (16, 17) together in different mutual positions. Ventilation device according to claim 1, wherein the manifold (10, 11) comprises a main manifold part (16) which is provided with the main connection (19) and at least one auxiliary manifold part (17) is provided with one or more auxiliary connections 20). Ventilation installation according to claim 2, wherein the coupling means (18) are provided between the main manifold part (16) and an auxiliary manifold part (17). Ventilation device as claimed in claim 2 or 3, wherein the coupling means are provided between two auxiliary manifold parts. Ventilation installation according to one of the preceding claims, wherein the manifold (10, 11) has a polygonal cross-section and the manifold parts (16, 17) are offset in the longitudinal direction of the manifold, the coupling means (18) are located on or near transverse faces of adjacent manifold parts. Ventilation device according to claim 5, wherein the number of mutually different positions in which the manifold parts (16, 17) can be coupled to each other is equal to the number of corners of the polygonal cross-section of the manifold (10, 11). Ventilation device according to one of the preceding claims, wherein the coupling means (18) comprise screw thread means. Ventilation device as claimed in claim 7, wherein the pitch of the screw means (18) is designed such that the connection between the screw means is established by a stroke with a revolution whose magnitude is the inverse of an entire circle of the number of possible mutual positions of the respective adjacent manifold parts (16, 17). Ventilation device according to any one of the preceding claims, wherein all manifold parts (16, 17) have a through-going chamber part which opens at opposite ends of the manifold part, which chamber parts connect to each other and together form the inner chamber (30) of the manifold, and at opposite ends of the chamber, closure covers (29) are provided at the extreme manifold parts. 10. Ventilation device according to one of the preceding claims, wherein at least one of the auxiliary connections (20) is closed by a closing cover. Ventilation device according to one of the preceding claims, wherein at least one of the auxiliary connections (20) is provided with a flow regulator (24), such as a flow control valve, for controlling the air flow through that connection. Ventilation device according to claim 11, wherein at least one measuring system (29) is provided for measuring a property of the air at the flow controller and a control system (25) for controlling the flow controller on the basis of the measurement measured by the measuring system property of the sky. Ventilation device according to claim 12 or 13, wherein the flow regulator (24), the measuring system (29) and the control system (25) are included in a cassette (22) and at least one of the manifold parts (16, 17) is provided with a cassette room (23) in which the cassette is included. Ventilating device according to claim 13, wherein the cassette chamber (23) has a guide (26) by means of which the cassette can be guided in the cassette chamber or out of the cassette chamber. A ventilating device according to claim 14, wherein the (guide of the) cassette chamber (23) opens onto the exterior of a manifold part (16, 17) and is closed there by a cover (28). Ventilation device according to claim 15, wherein a plurality of adjacent manifold parts (16, 17) each have a cassette chamber (23), which cassette chambers are closed by a common cover (28). A ventilating device according to any one of claims 12-16, wherein the measuring system comprises a sensor unit (29) for measuring the CO2 content, the air humidity and the like of the air. A manifold (10, 11) for a ventilation device according to any one of the preceding claims, comprising a plurality of manifold parts (16, 17) and coupling means (18) by means of which the manifold parts are mutually coupled, characterized in that coupling means are designed for coupling the manifold parts together in different mutual positions.