The present invention relates to a supply air device comprising an outflow structure directing a supply air flow into a room. The supply air flow comprises primary air and secondary air. The primary air flow entrains a flow of secondary air from the room to flow to the supply air device and further to return to the room.
For temperature controlling of rooms, it has become common to provide the rooms with supply air devices, wherein primary air supplied from a central ventilation system is blown from nozzles inside the supply air device to be mixed in a discharge structure with a secondary air flow from the room entrained by the supply air flow. The air mixture formed by the primary and secondary air is led from the supply air device into the room as the supply air flow. The secondary air entrained from the room enters the supply air device via a temperature controlling device which enables the temperature controlling of the secondary air. This kind of supply air device controls internal thermal conditions of the room.
In some cases the secondary air is led instead of or in addition to a temperature controlling device through a filter in order to remove impurities from indoor air. The filter causes a flow resistance, which is not advantageous for the function of the supply air device. The flow resistance reduces the amount of secondary air flow, wherein the filtered secondary air flow does not have a significant effect on the quality of indoor air or temperature of indoor air, when the supply air device comprises a temperature controlling device. In other words, the filter of the supply air device restricts the secondary air flowing through the filter, resulting in an excessive reduction in removing impurities and in the temperature controlling efficiency of the supply air device comprising the temperature controlling device.
By increasing the primary air flow of the central ventilation system, it may be possible to increase the secondary air flow and therefore air purification and/or temperature controlling that is cooling or heating. However, among other things, increasing the primary air flow increases energy consumption and may lead to a need for bigger structures for the air flows of the central ventilation system. Increase of the primary air flow can also increase the size of the ventilation system, for example, size of air ducts and/or air handling units.
It is an aim of the present invention to provide a supply air device comprising an outflow structure that increases air circulating efficiency (secondary air flow (litres/second (I/s))/primary air flow (Ws)) of a supply air device. The outflow structure comprises an outflow channel structure comprising at least one outflow channel and a nozzle structure comprising at least one nozzle. The outflow channel is arranged to be fixed in a distance from the nozzle and on a side of the supply air device.
According to a first embodiment, there is provided a supply air device comprising an outflow structure comprising a nozzle structure and an outflow channel structure, wherein the nozzle structure comprises a plurality of nozzles which are arranged to the bottom of the supply air device for supplying primary air. The outflow channel structure comprises an outflow channel, a first end of which is arranged in a first distance from said plurality of nozzles so that a mixing chamber is formed between said plurality of nozzles and the first end of the outflow channel and so that said plurality of nozzles supply the primary air towards the first end of the outflow channel and in a second distance from the side of the supply air device. The second end of the outflow channel is arranged outside the supply air device. The primary air entrains secondary air from outside the supply air device to flow to the mixing chamber to be mixed with the primary air in the mixing chamber before the primary air and the secondary air enter the outflow channel through the first end of the outflow channel and flow out of the supply air device through the second end of the outflow channel.
According to an embodiment, the second end of the outflow channel is turned away from the supply air device. According to an embodiment, the second end of the outflow channel is directed downwards. According to an embodiment, the outflow channel is a uniform and unobstructed structure perpendicular to the air flowing direction in the outflow channel. According to an embodiment, the cross-sectional area which is perpendicular to the air flow of the outflow channel remains constant. According to an embodiment, the second end of the outflow channel is wider in the vertical direction and narrower in the horizontal direction than the first end of the outflow channel. According to an embodiment, the outflow channel structure comprises an outflow channel for each side of the supply air device. According to an embodiment, the nozzle structure is a nozzle channel structure arranged in a distance from the bottom of the supply air device forming a circulation space between the bottom of the supply air device and the nozzle channel structure. According to an embodiment, the nozzle structure comprises a plurality of nozzles arranged to the bottom of the supply air device. According to an embodiment, the supply air device further comprises a filter. According to an embodiment, the supply air device comprises two or more nozzle channel structures with separate outflow channel structures.
In the following, various embodiments of the invention will be described in more detail with reference to the appended drawings, in which
A supply air device according to the invention that is arranged to be fixed to a ceiling or wall comprises an outflow structure. The term supply air device covers in this context also, for example, local exhaust ventilation devices and air purifiers in addition to supply air devices. The outflow structure of the supply air device comprises a nozzle structure for supplying primary air and an outflow channel structure for supplying primary air and secondary air to a room. The air supplied by nozzles of the nozzle channel structure of the supply air device is called primary air. The primary air may be received, for example, from the central ventilation system or from the same room, from some other space/room or from outdoors by using a separate fan. At the same time, secondary air is drawn back into the supply air device to be mixed with primary air and to be supplied to the room through outflow channels. The outflow structure arrangement according to the invention increases the air circulating efficiency (secondary air flow (litres/second (I/s))/primary air flow (Us)) of a supply air device and thereby enhances the purification or temperature controlling of air in the room, if the supply air device is also equipped with a filter and/or a temperature controlling device. The filter causes a flow resistance, which reduces the amount of secondary air flow. If an amount of secondary air decreases, the filtered secondary air flow may not have a significant effect on the quality or temperature of indoor air.
The nozzle structure may be a plurality of separate nozzles arranged traditionally to the bottom of the air supply device for supplying primary air. The sides of the supply air device may extend directly perpendicular in respect to the bottom. The number of nozzles, the diameter and shape of nozzles, the locations of nozzles at the bottom of the supply air device and/or the distance between nozzles may be selected to be suitable for the purpose of the supply air device. The nozzles may be arranged, for example, in a line or the like next to one or more sides. The bottom of the supply air device is the side of the supply air device that is against the first end of an outflow channel(s) through which air flows from the supply air device to the room. The bottom of the supply air device is arranged to be fixed towards the ceiling or wall when the supply air device is fixed to the ceiling or wall.
Alternatively the nozzle structure may also be a nozzle channel structure that is a peripherally closed duct system, as separate ducts forming a duct system or as a duct system comprising at least two separate duct sections. The sections may be connected together, for example, by connecting parts or the duct system may comprise at least two separate duct sections in which case a closed duct system is divided into at least two separate duct sections by a compartmentation wall(s). The nozzle channel structure may have various shapes. It may have, for example, a shape of a hollow rectangle with or without round corners, toroid, hollow oval or any other suitable shape when the supply air device is fixed to a ceiling or wall of a room and seen from below. The nozzle channel structure comprises a plurality of nozzles that are perforations with or without collars arranged on the perimeter of the nozzle channel structure in a distance from each other. The number of nozzles, the diameter and shape of nozzles, the locations of nozzles relative to the longitudinal line of one or more parts of the nozzle channel structure and/or the distance between nozzles may be selected to be suitable for the purpose of the supply air device. It is also possible that the location or the diameter or the shape of nozzle perforations or the distance between nozzles of the same nozzle channel structure vary. It is also possible that instead of a plurality of nozzles there is one long nozzle, for example, a slit nozzle. The nozzle channel structure may be made, for example, of metal or other suitable material. Ducts or parts of nozzle channel structures may have different cross-sections. A cross-section of duct(s) or part(s) of a nozzle channel structure may be circular, rectangular or an oval shape etc. Furthermore, cross-sections of ducts/parts of one nozzle channel structure may vary. For example, one or more part(s) of a nozzle channel structure may have rectangular shape and one or more other part(s) of the same nozzle channel structure may have circular shape. The nozzle channel structure may be formed from a uniform channel or channel modules with a monolithic profile, which channel modules are configured to be fastened, for example, one after the other, so that each nozzle channel module constitutes a part of the nozzle channel structure. Inside the supply air device, the nozzle channel structure is arranged in a distance from a bottom of the supply air device, but still in the bottom of the supply device. When the nozzle channel structure is arranged in a distance from the bottom of the supply air device, it may increase entrainment of the secondary air by enabling circulating of the secondary air from a first side (a center side) of the primary air flow to the other side of the primary air flow through the circulating space between the bottom of the supply air device and the nozzle channel structure, wherein the other side is between the primary air flow and an outer wall of a discharge channel of the supply air device. By the nozzle channel structure the amount of secondary air may be increased and the quality and/or temperature of indoor air can be kept on an effective level.
It should be noted that even if nozzles are arranged in the bottom or in a nozzle channel structure that is arranged in a distance from the bottom, in this context they both are arranged at the bottom of the supply air device.
Furthermore, it may be possible to adjust the nozzles to blow towards sides i.e. the outer walls of the supply air device or towards a circulation air opening i.e. the center part of the supply air device.
The outflow channel structure comprises outflow channels, for example, 1-4 channels that guide the air mix from the supply air device to the room. A supply air device may comprise an outflow channel in its each side or in 1 to 3 of its sides. The air mix comprises primary air and secondary air. The primary air is supplied by nozzles towards the outflow channel(s) and the secondary air is entrained by the primary air from the room. The outflow channel is arranged inside the supply air device so that the first end of the outflow channel is arranged in a first distance from the nozzles, substantially under the nozzles if the supply air device is fixed to a ceiling and so that the plurality of nozzles supply the primary air towards the first end of the outflow channel and in a second distance from a side of the supply air device. A mixing chamber is formed between the plurality of nozzles and the first end of the outflow channel. The second end of the outflow channel is arranged outside the supply air device. The side of the supply air device is one of the substantially vertical walls of the supply air device, when the device is fixed to the ceiling. The height of the area between the nozzle structure and the outflow channel that is the mixing chamber may be called a vertical distance. The distance between the side of the supply air devices and the outflow channel may be called a horizontal distance.
The second end of the outflow channel may be turned away from the supply air device for supplying air mix to the side of the supply air device or it may be directed downwardly for supplying air mix towards the floor, or anything in between.
It is also possible that the width of the second end of the outflow channel is wider so that the air may be supplied to the wider area. Despite the wider width of the second end of the outflow channel, the cross-sectional area of the second end of the outflow channel is the same or at least substantially the same as the cross-sectional area of the first end of the outflow channel. In other words, the cross-sectional area of the outflow channel remains constant over the entire length of the outflow channel, wherein the cross-sectional area is the area of the outflow channel that is perpendicular to the air flow flowing in the outflow channel. This means that if the width of the second end of the outflow channel is wider than the width of the first end of the outflow channel, the height of the second end of the outflow channel is smaller than the height of the first end of the outflow channel.
It is also possible that the shape of the cross-section of the outflow channel changes. For example, the shape of the cross-section of the second end of the outflow channel and/or the shape of the middle part of the outflow channel may be different than the shape of the cross-section of the first end of the outflow channel, or the shape of the cross-section of the first end of the outflow channel and/or the shape of the middle part of the outflow channel may be different than the shape of the cross-section of the second end of the outflow channel. Despite the changed shape of the cross-section, the cross-sectional area of the outflow channel remains constant or substantially constant throughout the length of the outflow channel.
Without an outflow structure according to the invention, the air circulation effectiveness may not be as effective as when an outflow structure with outflow channels is used, because the secondary air is not entrained by the primary air as effectively.
As can be seen from
Outflow channels 210, 211 improve circulation effectiveness which therefore improves removal of impurities from room air, if a filter is used, and/or temperature controlling, heating or cooling, of room air, if the supply air device is equipped with a heat exchanger, for example, heating or cooling coil.
The first nozzle channel structure 601a, the lower one in this figure, is again arranged at a distance from the bottom 620 of the supply air device 600 and the second nozzle channel structure 601b is attached at a distance from a bottom part of the separating wall 610. The bottom part of the separating wall 610 is the part of the separating wall 610 that is under the second nozzle channel structure 601b. The supply air device 600 comprises also a filter 606. Primary air may be led into the supply air device 600 via a supply air duct 618 from a central ventilation system, a room, outside etc. In the supply air device 600 primary air is led into a supply air chamber 602. From the supply air chamber 602 the primary air is led to the nozzle channel structures 601a, 601b comprising a plurality of air nozzles. From the nozzle channel structures 601a, 601b the primary air is led through air nozzles of the nozzle channel structures 601a, 601b into the mixing chambers 603a, 603b as primary air flows 605a, 605b. The primary air flows 605a, 605b blown into the mixing chambers 603a, 603b entrain secondary air 607a, 607b into the supply air device 600 from the room wherein the supply air device 600 lies through a circulation air opening. Inside the supply air device 600 the secondary air 607a, 607b flows through the filter 606 on its way to the mixing chambers 603a, 603b. A part of the secondary air 607a, 607b may circulate through the circulation spaces between the first nozzle channel structure 601a and the bottom of the device 600 or through the circulation space between the second nozzle channel structure 601b and the bottom part of the separating wall 610 before they mix with the primary air of primary air flows 605a, 605b in the mixing chambers 603a, 603b. From the mixing chambers 603a, 603b, the mixture of primary air and filtered secondary air flows to the outflow channels 604a, 604b and through them out of the device 600. Before entering to the outflow channels 604a, 604b there are notches 611a, 611b, which also guide the air mix to the outflow channels 604a, 604b. Again the structure of the supply air device 600 comprising the nozzle channel structures 601a, 601b and the mixing chambers 603a, 603b, but also the outflow channels 604a, 604b and the notches 611a, 611b increase the air circulating efficiency of the supply air device 600.
When compare the supply air device 900 of
The supply air device 900 also comprises a notch 910 formed to the inner of the side supply air chamber 907. In this embodiment of
The indented supply air chamber shown in
A device comprising an outflow structure according to the invention may increase the secondary air flow even more by increasing entrainment of the secondary air and increasing exhaustion in the mixing chamber and/or in the outflow channel so that the amount of the secondary air increases, thereby enhancing the purification or temperature controlling of air in the room, than a device comprising only one outflow structure. However, the device comprising one outflow structure according to the invention may entrain the secondary air flow still more than prior art solutions.
It should be also noted that it is possible to use a supply air device comprising an outflow structure according to the invention also for other gases than air.
It is obvious that the present invention is not limited solely to the above-presented embodiments, but it can be modified within the scope of the appended claims.
Number | Date | Country | Kind |
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20165210 | Mar 2016 | FI | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FI2017/050127 | 2/28/2017 | WO | 00 |