SE511340C2 - Roof or ceiling mounted air extractor - contains perforated partition wall between pressurised box and air distributor and uses nozzles in distributor to reduce draughts - Google Patents

Abstract

Large amounts of air are supplied without creating draughts from large roof or ceiling areas to rooms beneath them using a pressurised box (11) located above an air distributor (14). A perforated partition wall (15) is positioned between the box and distributor and components (19) located in the partition wall holes are used to compensate for varying air distribution in the box. Adjustable nozzles (17) for the distributor force the air leaving the extractor to rotate and become entrained with air already in the room. These nozzles also reduce the velocity of the air leaving the extractor and create a gentle downwards movement of air over the entire area underneath the ceiling or roof.

Description

llll: l 'H un: rlrlww »» i - | Il: 'll i: I :::' || mi: m: vw-l w-: r nn 'lïlf 511340 and 2 10 15 20 25 30 35 The invention is characterized for this purpose by the features which appear from the accompanying patent claims.

The supply air device according to the invention thus comprises an air from the connection ducts receiving pressure box as well as an air to the room distributing unit.

The pressure box is delimited from the distribution unit with apertured dividers. walls and the air distribution unit is equipped with adjustable nozzles, which in use are arranged to give rotational movements of the outgoing to the room the air.

It is preferred to make the air distributing unit as a number of box-shaped cassettes. These are arranged next to each other inserted into the supply air device, wherein each cassette has a ceiling constituting the said partitions and a nozzle bottom. The openings may be provided with means for compensating for varying the air distribution in the pressure box. This may be necessary in low pressure boxes, for example, intended for lower ceiling heights, where air speeds may be too high high to enable the intended flow deflection between the pressure box and the the air distribution unit, ie to the cassettes, if applicable. It has shown it is particularly suitable to use the distribution plates described in our previously mentioned EP-B-507756. With the help of the distribution plates can thus the air distribution over the roof surface is controlled by turning the tiles.

Depending on the height of the roof box and the air distribution in the connection ducts need these are rotated either downstream or countercurrently for appropriate distribution shall be obtained.

The invention will now be described in more detail with reference partly to the appended claims drawing where figure 1 is a principle sketch of the supply air device seen from the side, the figures 2-4 show different details from a cassette to the supply air device according to the invention.

Figure 1 shows a horizontal supply air device 10 intended for ceiling mounting, which has a roof box 11 connected to a connection duct 12 from which the air is supplied in a direction indicated by the arrow 13. In the supply air device 10, several cassettes are mounted. 14, four of which are shown in parallel. Each cassette 14 has one roof 15 provided with a plurality of openings, a bottom 16 in which are arranged 10 15 20 25 30 35 3 511 340 nozzles 17, of which here six are shown. Each cassette 14 also has entire side walls 18.

Figure 2 schematically shows a cassette 14 according to the invention seen from the side.

The cassette consists of the ceiling 15, the side walls 18 and the bottom 16. The ceiling 15 is located a number of rotatable distribution plates 19 arranged in circular openings. IN the bottom 16 of the cassette 14 there are a number of nozzles 17 arranged and set to give a rotational movement of the exiting air from the cassette 14. In Figure 3 schematically shows a suitable placement of distribution plates 19 in a cassette roof 15, where the plates 19 are arranged in five parallel rows of five in each. Figure 4 shows the appropriate placement of nozzles 17 in the cassette bottom 16. The figure shows also appropriate air direction on outgoing air from each nozzle to achieve intended rotational effect.

Example: A supply air diffuser according to the invention with the outer dimensions 2400 X 1800 mm and the height 400 mm comprising 12 cassettes each with the dimensions 600 X 600 X 50 mm was mounted recessed in the ceiling 3 m above the floor in a laboratory room for flow measurements. Each cassette was built in the form of a box, whose roof consists of a perforated sheet with 5 X 5 holes with a diameter of 88 mm and the bottom consists of a perforated plate with 6 X 6 holes with a diameter of 55 mm. Stifab Farex distribution plates were mounted in the holes in the box roof, while Stifab Farex nozzles (according to pattern no. 55598) were mounted in the bottom of the cassette. Tests was carried out with a nominal air flow of 33 l / s per cassette, with a maximum value of 44 l / s and a minimum of 11 l / s. The temperature has during all tests been about 5 ° C lower than the room temperature. The air movements were visualized with by means of smoke supplied in the inlet to the supply air device. Air speeds and the temperature was measured with instrument type Dantec 54 N 10.

Conventional arrangements for the supply of air vertically down from the ceiling are terminated normally with a perforated plate to get an even air distribution over the donut surface.

Therefore, such an arrangement was initially tried. Part 16 of the roof cassette was therefore replaced with a perforated plate. The highest speeds that were then measured at a distance of 1.2 m under the ceiling at a nominal air flow of 33 l / s per cassette was in the range C, 45-0.50 m / s. These are too high speeds for that be acceptable from a comfort point of view. 511 340 4 With the device described according to the invention with Stifab Farex nozzles as above, at the same air flow, the highest air velocities were obtained at 0.20 m / s at the same distance from the roof. At the level of 1.8 m under the roof, l à 2 was obtained cm / s lower speeds. This speed reduction is a sign that one ... fl-. J .Jr .i 5 high co-design of room air has been obtained. In the case of perforated sheet metal, lowers the acceleration of the air in the occupancy zone due to the very low co- in this case. v: rvdiw W.

Test at the two other air flows 11 resp. 44 l / s per cassette affected 10 only marginally the highest air speeds. This also indicates that it proposed design really creates an even air-distribution with high l IW w vn-ww li co-design of room air. 15 in r

Claims (2)

511 511 340 CLAIMS 1. Supply air devices (10) for draft-free supply of large air volumes from large roof surfaces to underlying premises comprising an air receiving pressure box (11) and an air distribution unit (14) arranged thereunder, characterized by that the pressure box (1 V1) is delimited from the distribution unit (14) by a partition wall (15) provided with an opening, that the openings are provided with means (19) intended to compensate for varying air distribution in the pressure box (1 1) and that the air distribution unit (14) is provided with adjustable nozzles (17), which in use are arranged to give rotational movements of the air leaving the room, whereby high co-injection of room air is supplied. Supply air diffuser according to claim 1, characterized in that the air distributing unit (14) consists of a number of box-shaped cassettes arranged next to each other inserted in the supply air diffuser (10), each cassette having a roof forming part of the screen wall (15) and a bottom (16) provided with nozzle-oiiñ) intended and adjustable to provide one. the rotational movement of the outgoing air from each cassette in the distribution unit (14). 511 340 lO 15 20 PATENT REQUIREMENTS Supply air device (10) for draft-free supply of large amounts of air from large roof surfaces to underlying premises comprising an air receiving pressure box (11) and an air distribution unit (14) arranged below, characterized by the pressure box (11) is delimited from the distribution unit ( 14) with an apertured shell wall (15), that the openings are provided with means (19) intended to compensate for varying air distribution in the pressure flap (11) and that the air-distributing unit (14) is provided with adjustable nozzles (17), which in use are arranged to give rotational movements of the air leaving the room, whereby high co-injection of room air is supplied. Supply air diffuser according to claim 1, characterized in that the unit air distributing unit (14) consists of a plurality of laden cassettes arranged next to each other inserted into the supply air diffuser (10), each cassette having a roof forming part of the screen wall (15) and a bottom (16). provided with the nozzles (17) intended and adjustable to provide for the rotational movements of the outgoing air from each cassette in the distribution unit (14).