EP0856709A1 - Air diffusion system - Google Patents

Abstract

The air diffusion system (1) consists of an outer duct (10) which is supple and is able to deform under the action of air passing through it. The outer duct is connected to a blower (60). A pressure chamber (50) receives air from the blower and a distribution chamber (70) is connected to the pressure chamber by a supple and air-permeable sleeve (80). The distribution chamber surrounds the compression chamber and has at least one diffusion zone.

Description

The present invention relates to an air diffusion system of the delimited type externally by a flexible and deformable sheath under the action of air. The invention applies in particular to heating, cooling, humidification or ventilation of a room.

For heating, air conditioning or ventilation of industrial premises or commercial, it is known to use air diffusion systems of the type constituted a cylindrical flexible sheath of great length, provided to allow diffusion air introduced to its air inlet orifice by a blowing means.

In a known embodiment which is for example illustrated by the English patent document GB-A-2 135 442, said flexible sheath consists of a breathable fabric or fabric, for example, the fabric or fabric can be made of various materials. In known manner, said fabric or said canvas are breathable, or they have a plurality of hole alignments on their dissemination areas. These alignments are then respectively performed according to generators of the flexible sheath, when the latter is inflated by means of blowing.

These flexible air diffusion systems have the advantage of being easily mountable, dismountable and transportable, due to their lightness, and being light expensive compared to sheet metal sheaths, also used. In addition, they work with a reduced noise level.

However, these systems are not entirely satisfactory in the case where you want to vary the air blowing rate in the corresponding duct, because the aforementioned holes are precisely sized to ensure air diffusion satisfactory for a predetermined blowing flow.

More particularly, a major drawback of these systems lies in the means that, at a reduced blowing rate, the air which is blown into each flexible duct in exits at a very low flow rate through the holes which are close to its entry orifice comparison of the air leaving the other end of the duct, due to the static pressure of the air at the inlet of the duct which is then substantially lower than that existing at the end sheath. It turns out that this air pressure in the vicinity of said inlet orifice is insufficient to ensure correct air distribution.

When the blowing rate is lower than that for which the flexible duct is expected, experience shows that air diffusion does not take place in a unidirectional at the output of each generator of the sheath. Therefore, the room air conditioning or heating is not adequately provided.

The aim of the present invention is to propose an air diffusion system of the type delimited externally by a flexible and deformable sheath under the action of air, which is connected to blowing means and which makes it possible to provide, for air flows can vary within a relatively wide range including reduced flows, a distribution of the air flow diffused by said system which is uniform over the length of the latter and with only one direction of diffusion predetermined, for example normal to the zone or zones of diffusion of said system.

To this end, such an air diffusion system according to the invention comprises, part, an overpressure chamber provided to receive the air blown by means of blowing and, on the other hand, at least one distribution chamber, said or each distribution chamber being provided to communicate with said distribution chamber overpressure via a common flexible and breathable wall, called expansion wall, the or each distribution chamber being provided with at least one diffusion zone designed to allow the diffusion of air, said zone being localized in the wall of said flexible sheath, said flexible expansion wall being located in look at said or each corresponding broadcast area.

According to one embodiment of the invention, said distribution chamber surrounds said overpressure chamber, for example coaxially. In this last case, said chambers advantageously have a shape substantially cylindrical.

According to another characteristic of the invention, said or each chamber distribution is delimited externally by a flexible diffusion wall and deformable.

A broadcasting system according to the invention is for example of the delimited type externally by a flexible cylindrical sheath, and said or each flexible wall of trigger may then consist of at least one partition mounted on said sheath to inside thereof, so as to form said overpressure chamber and said or said distribution chambers.

la Fig. 1 est une vue latérale d'un système de diffusion d'air selon un premier mode de réalisation de l'invention,

la Fig. 2 est une vue en coupe selon le plan II-II du système de diffusion d'air représenté à la Fig. 1,

la Fig. 3 est une vue latérale d'un système de diffusion d'air selon un second mode de réalisation de l'invention,

la Fig. 4 est une vue en coupe selon le plan IV-IV du système de diffusion d'air représenté à la Fig. 3,

la Fig. 5 est une vue en coupe transversale d'un troisième mode de réalisation d'un système de diffusion d'air selon l'invention, et

la Fig. 6 est une vue en coupe transversale d'un quatrième mode de réalisation d'un système de diffusion d'air selon l'invention.

The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being made in relation to the accompanying drawings, among which:

Fig. 1 is a side view of an air diffusion system according to a first embodiment of the invention,

Fig. 2 is a sectional view along the plane II-II of the air diffusion system shown in FIG. 1,

Fig. 3 is a side view of an air diffusion system according to a second embodiment of the invention,

Fig. 4 is a sectional view along the plane IV-IV of the air diffusion system shown in FIG. 3,

Fig. 5 is a cross-sectional view of a third embodiment of an air diffusion system according to the invention, and

Fig. 6 is a cross-sectional view of a fourth embodiment of an air diffusion system according to the invention.

The air diffusion system 1 shown in Figs. 1 and 2 is delimited externally by an air permeable sheath 10, which is intended to be held on a ceiling 20 of a room 30 by a fixing system 40.

According to an important characteristic of the present invention, said sheath 10 is provided flexible and deformable under the action of the air it is intended to receive, and it is for example made of a material of the fabric type.

It will be noted that the system 1 according to the invention could also be fixed by vertically in said room 30. The diffusion system 1 consists of a overpressure chamber 50 provided, on the one hand, for receiving air supplied by a blowing means 60 to which it is connected and, on the other hand, to convey it to a distribution chamber 70 to which it is also connected and which communicates with the room 30 by said flexible sheath 10. Said chamber 70 is in particular provided for ensure an equal distribution of the pressure of the air diffused along the flexible sheath 10 and, consequently, of the flow rate of the air diffused along said sheath 10.

In the exemplary embodiment shown in FIG. 1, the bedroom overpressure 50 is delimited by a flexible wall 80 of generally cylindrical shape which is breathable. The wall 80 is connected at one of its ends 81 to a enclosure 90 comprising the blowing means 60, by a section 82 of shape frustoconical and diverging in the direction of said enclosure 90.

The distribution chamber 70 admits, on the one hand, said flexible wall 80 as internal wall and, on the other hand, said flexible sheath 10 as external wall. As can be seen in Fig. 2, the flexible sheath 10 surrounds coaxially and spaced apart the flexible wall 80 of the overpressure chamber 50, except that said end 81 of wall 80 is substantially coincident with end 11 of the sheath 10 which is opposite. As an indication, the flexible wall 80 is for example separated flexible sheath 10 from a distance of between 3 and 10 cm.

The wall 80 and the flexible sheath 10 may consist of a fabric partially or completely porous, or of an airtight fabric having a plurality of perforations (not shown). These are for example aligned along generatrices of the corresponding cylindrical surfaces.

As for the blowing means 60, it is for example constituted by a fan which is connected upstream to a conduit 91.

Also shown in FIG. 1 a recycling conduit 92 provided for supply the overpressure chamber 50 with air collected in the room 30, in addition of duct 91.

The air diffusion system 1 corresponding to said first mode of embodiment of the invention operates in the following manner.

Air is continuously sucked into the conduits 91 and 92 via the means of supply air 60 (see arrow A in Fig. 1). We see in this Fig. that the air moved by the blowing means 60 circulates in the overpressure chamber 70 substantially along an axial direction thereof (see arrows B).

Due to the air permeability of the flexible wall 80 of the overpressure 50, the air which is compressed in said chamber 50 passes continuously said flexible wall 80 with a pressure drop and consequently penetrates into the contiguous distribution chamber 70 (see arrows C in Fig. 1).

We have seen that each air jet expanded by the expansion wall 80 comes out of the flexible sheath 10 in a direction substantially radial with respect to the latter (see arrows D in Fig. 1), regardless of the location of said jet along said sheath 10, so that the air diffuses radially in the room 30.

An air diffusion system 100 corresponding to a second mode of embodiment of the invention is shown in Figs. 3 and 4.

Regarding this second mode which will be described below, we have assigned numbered references increased by 100 for the structural elements of this second mode which are analogous to those described in said first mode, this for a better understanding of the description.

The air distribution system 100 is delimited externally by a sheath flexible 110 cylindrical and breathable which is intended to be maintained on the ceiling 120 of a room 130 by a fixing system 140. This sheath 110 is by example made of a material of the fabric type, like the sheath 10 above.

As previously, it will be noted that said system 100 could be fixed vertically in room 130. The diffusion system 100 consists of a overpressure chamber 150 provided, on the one hand, for receiving air supplied by the minus one duct 191 (two ducts 191 are shown in Fig. 3) to which it is connected and, on the other hand, to route it to at least one distribution chamber 170 to which it is also connected and which communicates with room 130 by said flexible sheath 110.

The flexible sheath 110 is provided in its internal part with at least one flexible partition 180 breathable. This partition 180 can also be constituted of a fabric type material, like the flexible wall 80 above. The bedroom overpressure 150 and the distribution chamber 170 which communicates with it are separated by said flexible partition 180, so that the overpressure chamber 150 is connected to said air supply ducts 191 via the sheath 110, on the wall side of which said conduits 191 are mounted (the blowing means including are respectively provided said conduits 191 are not shown).

In addition, the system 100 is provided with a recycling duct analogous to said conduit 92 (not shown) and designed to supply the overpressure chamber 150 with air collected in room 130.

In the embodiment of Figs. 3 and 4, the flexible sheath 110 is provided with a single flexible partition 180, so that the diffusion system 100 has a single distribution chamber 170.

As can be seen in the example in Fig. 3, the flexible partition 180 is generally parallel to the direction of the generatrices of the cylindrical surface of the flexible sheath 110. Consequently, the overpressure and distribution chambers 150 and 170 are respectively delimited by truncated cylinders having said flexible partition 180 in common.

The air diffusion system 100 corresponding to said second mode of embodiment of the invention operates in the following manner.

Air is continuously blown into the ducts 191 and the said duct recycling (see arrows A in Fig. 3). We see in this Fig. let the air spread in the overpressure chamber 150 substantially in an axial direction thereof (see arrows B).

Due to the breathable nature of the flexible partition 180, the air which is compressed in said chamber 150 permanently crosses said partition 180 with a pressure drop and enters the distribution chamber 170 (see arrows C in Fig. 3).

We could see that each air jet expanded by the expansion partition 180 leaves the flexible sheath 110 in a substantially radial direction relative to this (see arrows D in Fig. 3), regardless of the location of said jet along of said sheath 110, so that it diffuses radially in the room 130.

There is shown in FIG. 5 a third embodiment of a system of air diffusion according to the invention.

In the air diffusion system 100 shown in cross section at the Fig. 5, the flexible sheath 110, for example made of a material of the fabric type, has in its internal part two flexible expansion walls 181 and 182. These walls flexible 181 and 182, for example also of the fabric type, respectively form partitions between, on the one hand, a central overpressure chamber 150 and, on the other hand, two distribution chambers 171 and 172 communicating with said chamber 150. In addition, the overpressure chamber 150 is connected to a means of blowing (not shown).

As can be seen in Fig. 5, the distribution chambers 171 and 172 are symmetrical to each other with respect to the median plane of the flexible sheath 110 which is parallel to the ceiling 120 of room 130.

The diffusion system 100 of FIG. 5 works similarly to those which have been described with reference to Figs. 1 and 4, except that the air blown into the compression chamber 150 passes through each flexible partition 181, 182 with a pressure drop and say through the part of the flexible sheath 110 which is located in look of the corresponding partition 181 or 182 in a radial manner.

In the air diffusion system 100 shown in cross section at the Fig. 6 and corresponding to a fourth embodiment of the invention, the sheath flexible 110, for example of the fabric type, has in its internal part three walls flexible expansion 181, 182 and 183. These flexible walls 181, 182 and 183, for example also in fabric, respectively form partitions between, of a on the one hand, a central overpressure chamber 150 and, on the other hand, three distribution 171, 172 and 173 communicating with said chamber 150. The overpressure 150 is connected to a blowing means (not shown).

As can be seen in Fig. 6, two of said distribution chambers 171 and 173 are symmetrical to each other with respect to the third chamber 172, of such that the flexible expansion wall 182 corresponding to said chamber 172 is perpendicular to the flexible expansion walls 181 and 183 of said chambers 171 and 173.

The diffusion system 100 of FIG. 6 works similarly to those which have been described with reference to Figs. 1 to 4, except that the air blown into the compression chamber 150 passes through each flexible partition 181, 182, 183 with a pressure drop and diffuses through the part of the flexible sheath 110 which is located in look of the corresponding flexible partition 181, 182, 183 in a radial manner.

It will be noted that the diffusion system 1, 100 according to the invention could comprise several diffusion zones 10, 110 delimiting externally each distribution chamber 70, 170, 171, 172, 173, so that each wall flexible trigger 80, 180, 181, 182, 183 in communication with the overpressure 50, 150 is located opposite each diffusion zone 10, 110.

It will also be noted that the diffusion system 1, 100 according to the invention could be provided with air intake means 91, 92, 191 positioned in a way different from that illustrated in Figs. 1 and 2, provided that said means 91, 92, 191 are connected to the overpressure chamber 50, 150 of said system 1, 100

Due to the subdivision of the air diffusion system 1, 100 according to the invention in an overpressure chamber 50, 150 and at least one distribution chamber 70, 170, 171, 172, 173, it is possible to vary the supply air flow rate of said system 1, 100 within a wide range including reduced flow rates, while having a radial diffused air flow along the flexible sheath 10, 110, unlike the systems of the prior art.

In addition, the diffusion system 1, 100 according to the invention makes it possible to ensure a constant pressure and outlet flow for the air jets distributed over the length of the flexible sheath 10, 110, so that said system provides air conditioning, ventilation or satisfactory heating in the space of room 30, 130 concerned.

When the blowing rate is reduced, experience also shows that air diffusion characteristics, in particular its speed at the outlet of the duct flexible 10, 110, decrease in intensity to a lesser extent than said flow of blowing using the system 1, 100 according to the invention. Advantageously, said system 1, 100 makes it possible to maintain said diffusion characteristics at values higher than the corresponding minimum values which are required for the correct heating or cooling of room 30, 130 considered.

• Longueur de la gaine souple 10, 110: 29 m.
• Diamètre de ladite gaine 10, 110: 90 cm.
• Distance entre la paroi souple 80 ou la cloison souple 180 de détente et la gaine souple 10, 110: 5 cm.
• Pression statique de fonctionnement dans le système de diffusion 1, 100: comprise entre 60 et 500 Pa.

As an indication, tests have shown that it is possible to use an air diffusion rate of between 20% and 100% of a nominal value, for example equal to 50,000 m ³ / h, for a system 1, 100 diffusion according to the invention having the following characteristics, while maintaining the monodirectional characters and uniformly distributed in pressure and flow of the air jets diffused.

• Length of flexible sheath 10, 110: 29 m.
• Diameter of said sheath 10, 110: 90 cm.
• Distance between the flexible wall 80 or the flexible expansion partition 180 and the flexible sheath 10, 110: 5 cm.
• Static operating pressure in the diffusion system 1, 100: between 60 and 500 Pa.

Said air diffusion system 1, 100 therefore makes it possible to ensure an air flow broadcast in room 30, 130 which is likely to evolve into a range including reduced flows, while providing a unidirectional and uniform distribution of the air when it leaves said system 1, 100.

In addition, the system 1, 100 according to the invention is adapted to operate at positive or negative temperatures, depending on the application envisaged.

Claims (5)

Air diffusion system (1, 100) of the type delimited externally by a sheath (10, 110) flexible and deformable under the action of air, said system (1, 100) being connected to blowing means (60), characterized in that it comprises, on the one hand, an overpressure chamber (50, 150) provided to receive the air blown by means (60) and, on the other hand, at least one distribution chamber (70, 170, 171, 172, 173), said or each distribution chamber (70, 170, 171, 172, 173) being provided to communicate with said overpressure chamber (50, 150) via a flexible and common wall (80, 180, 181, 182, 183) which is breathable, called a wall expansion, the or each distribution chamber (70, 170, 171, 172, 173) being provided with at least one diffusion zone provided to allow the diffusion of air, said zone being located in the wall of said flexible sheath (10, 110), said wall flexible expansion (80, 180, 181, 182, 183) being located opposite said or each corresponding broadcast area. Air distribution system (1) according to claim 1, characterized in that said distribution chamber (70) surrounds said overpressure chamber (50). Air diffusion system (1) according to claim 2, characterized in that said distribution chamber (70) coaxially surrounds said chamber overpressure (50), said chambers (50, 70) having a shape substantially cylindrical. Air diffusion system according to one of the preceding claims, characterized in that said or each distribution chamber (70, 170, 171, 172, 173) is delimited externally by a flexible diffusion wall (10, 110) and deformable. Air diffusion system (100) according to claim 1 or 4 of the type externally delimited by a flexible cylindrical sheath (110), characterized in that said or each flexible expansion wall (180, 181, 182) consists of at least a partition mounted on said flexible sheath (110) inside thereof, so as to forming said overpressure chamber (150) and said at least one pressure chamber distribution (170, 171, 172).

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