FR2790822A1 - NOZZLE FOR CONTROLLING AN AIRFLOW IN A PREMISES - Google Patents

Abstract

The air outlet nozzle (10) for controlling airflow includes a body portion (12) having a circular cross section, a rim (12') of the body portion (12) carrying a lip portion (13) similar to a cover which is attached to it. This air outlet nozzle (10) is divided, in the bore of the body part (12) of the nozzle, into channels (A1 and A2) by means of a partition (14) adjacent to the bore of the circular section body part (12). The surfaces (14', 14") of the partition (14) have a curved shape, whereby the surfaces (14', 14") of the partition (14) serve to guide the flow of air smoothly from the channels (A1 and A2), and the lip part (13) is adapted to partially cover the discharge opening of one of the channels (A2).

Description

Nozzle for controlling an air flow in a room

  invention relates to an air outlet nozzle for

  control the air flow in the space of a room.

  As regards the state of the prior art, reference is made to the following patent publications: SE 9100975, SE 7402503,

NO 169406 and SE 970031.

  An air outlet nozzle is known from these publications, the part of which controls the flow is produced with an inlet of circular section adjacent to a channel, the section of which tapers in the direction of the air flow and ends with an air deflector shaped so as to direct the air flow at an oblique angle,

  or parallel to the ceiling surface in the room.

  It is an objective of the present invention to provide an air outlet nozzle of an entirely new type comprising a body part of circular section in which is mounted an air guide partition similar to a baffle. The partition divides the bore of the circular section body into two channels, namely an AI channel and an A2 channel. With the help of the curved shape of the air guiding partition, the air flow can be smoothly discharged to the sides out of the structure of the air outlet nozzle. In addition, the end which ends the channel A2 is provided with a lip part which contributes to the lateral deflection.

of air flow.

  Without departing from the scope and spirit of the invention, it is also possible to envisage a modification of the structure of the air outlet nozzle according to which the air guiding partition is produced from a bimetallic plate with different coefficients of thermal expansion. This arrangement can be used to allow a

  deflection of the air flow controlled thermally.

  The invention can be applied to an air outlet on the wall, or on the ceiling. The air outlet nozzle in accordance with the invention is characterized in the manner indicated in the remainder of this patent application. In the following, the invention is described in more detail with reference to some embodiments of the invention illustrated in the accompanying drawings, intended to present non-limiting examples of the invention. In these drawings, FIG. 1A illustrates an embodiment of an air outlet nozzle in accordance with the invention for controlling an air flow, according to a partial perspective view; FIG. 1B illustrates the nozzle structure of FIG. IA, according to a perspective view and in partial section; Figure IC illustrates a sectional view of Figure IA, taken along line I - I; FIG. 1D illustrates the connection of the air outlet nozzle with an outlet opening 16 of a panel R using elastic fixing elements of the nozzle; and Figure 2 illustrates the lip portion of the nozzle, in a detailed view. Referring to FIG. 1A, the embodiment of an air outlet nozzle 10 shown in this figure comprises a part 12 forming a nozzle body, of circular cross section, and at its outlet end, a part forming lip 13, resembling a cover, which partially covers the outlet opening of the nozzle, so that the lip part is adjacent to the body part 12 of circular cross section. The bore of the body part 12 of the air outlet nozzle is divided by a partition 14 into two channels AI and A2, so that the air flow can be suitably divided so as to pass through the channel AI as well as channel A2, respectively. The partition 14 is a baffle structure whose shape is curved along its air guide surfaces 14 ′ and 14 ", as well as in the region of its end border 120. In this way, the baffle structure of the air guide partition 14 divides the bore of the body part 12 of circular section to form the channels A1 and A2. The terminal edge 140 of the air guide partition 14 extends to the level of the lip part 13, whereby the function of the air guiding partition 14 is to smoothly pass the air flow both from channel AI and from channel A2 at an oblique angle to the central axis X of the air outlet nozzle 10. As shown in FIG. 1A, the elements 15 in the form of elastic clamping claws arranged on both sides of the body part 12 serve to fix the outlet nozzle air 10, for example on a panel R in which a circular hole 16 is made in order to accommodate the has nozzle 10. The clamping claws 15 block the nozzle 10 on the panel R, while however facilitating the rotation of the nozzle 10 about its central axis

  X to adjust the direction of air flow as desired.

  Advantageously, the nozzle 10 is made of a polymer-based material. Figure 1B shows a partial sectional view of the structure illustrated in Figure 1A. As can be seen in FIG. 1B, the bore of the tubular body part 12 which has an entirely circular section is divided into two channels AI and A2 by means of the curved partition 14 which acts as a dividing cabinet, by its surfaces

14 'and 14 "air guide.

  Figure 1C shows a sectional view of Figure IA taken along line I - 1. As can be seen in Figure IC, the flow Li through the channel AI1 passes laterally being deflected towards the side in oblique direction relative to the central axis X under the guiding effect of the curved lower surface 14 'of the partition 14, while the air flow L2 through the channel A2 passes respectively on the other side of the curved partition 14 along its surface 14 ", being deflected similarly to the side in a direction oblique to the central axis X. In this case, the deflection of the flow L2 is also affected by the lip-shaped portion 13 which covers

  partially the discharge opening of channel A2.

  In FIG. 1D, the mounting of the air outlet nozzle 10 has been shown in an outlet opening 16 of a panel R so that the elastic snap-fastening elements 15, formed in the manner of clamping claws, hold the rear side R of the panel R. Thus, the snap-fastening element 15 prevents the nozzle 10 from sliding out of the outlet opening 16. The panel R guarantees a resting position against the annular collar 12a of the part forming the nozzle body 12 under the compression exerted by the end of the snap-fastening element 15. However, the snap-fastening of the fastening element 15 still allows manual rotation of the outlet nozzle air 10 around its central axis X so

  to control the air flow to a desired direction.

  FIG. 2 shows a detail of the air guide partition 14.

  Advantageously, the partition 14 is made of a polymer-based material, as is the entire structure of the air outlet nozzle 10. One can also envisage an embodiment of the invention in which the partition 14 is made from a bimetallic sheet having different coefficients of thermal expansion. The bimetallic material is produced by laminating sheets of different metals, and the difference between their coefficients of thermal expansion causes the partition 14 to adopt a curved position which depends on the temperature. Thus, the position of the partition 14 can be made self-adjusting, whereby the direction of flow of

  air discharge LI, L2 is thermally controlled.

  Alternatively, the partition 14 can be made from a memory metal. Likewise, this modification can be used to provide thermal control of the discharged air flow. In this case, the function of the partition 14 is similar to that described above. In addition, a plurality of air outlet nozzles of the present type can be arranged in a larger group forming a complete air diffuser, the air discharge pattern of which can be adjusted as desired by rotating individual nozzles in desired directions. It is possible to make another modification by making the vertical position of the partition 14 adjustable relative to the body part 12 of the air outlet nozzle 10 and relative to the plane of the panel R. It is then also possible to adjust the directions of the air discharge flows LI and L2. In this embodiment, the partition 14 can be adjusted, for example by mounting the partition in grooves made in the bore, drilling of the body part 12, and by providing that these grooves also serve as fixing means.

for the partition 14.

Claims (5)

Claims   1. Air outlet nozzle (10) for controlling an air flow, said air outlet nozzle (10) comprising a body part (12) having a circular cross section, an edge (12 ') of said body part (12) carrying a lip part (13) similar to a cover attached to it, characterized in that said air outlet nozzle (10) is divided, in the bore of said body part ( 12) of the nozzle, in channels (Al and A2) by means of a partition (14) adjacent to the bore of said body part (12) of circular section, in that the surfaces (14 ', 14 ") of the partition (14) has a curved shape, whereby said surfaces (14 ', 14 ") of the partition (14) serve to guide the flow of air smoothly from the channels (AI and A2), and that said lip portion (13) is adapted to partially cover the discharge opening of one of the channels (A2).   2. Air outlet nozzle (10) according to claim 1, characterized in that said air outlet nozzle (10) includes on the circumference of the body part (12) elastic fastening elements (15) whose clamping claws are adapted to come to bear on the surface of a panel element (R) in which is formed an opening (16) to allow the introduction of said air outlet nozzle, while said elements fixing (15) further facilitate the rotation of said air outlet nozzle about its central axis (X) to   control the air flow to a desired direction.   3. Air outlet nozzle (10) according to one of claims 1 and 2,   characterized in that said partition (14) is made of a bimetallic material produced by laminating sheets of two different metals having different coefficients of thermal expansion, or in that the partition is made from a memory metal, whereby the curved shape of the partition (14) becomes temperature dependent, thereby achieving thermal control of the flow   air passing through said air outlet nozzle (10).   4. Air outlet nozzle according to any one of the claims   above, characterized in that the position of said partition (14) is adjustable relative to said body part (12) of the nozzle along means   mounting of said partition (14) adapted in said body part (12).   5. Air outlet nozzle according to claim 1, intended to control an air flow, characterized in that said air outlet nozzle (10) is produced in a polymer-based material.