FR3111182A1 - Ventilation device for indoor cooling of a home - Google Patents

Abstract

The invention relates to a ventilation device (1), comprising: - a first part (11) comprising a first duct (117) and first (110) and second (114) openings at first and second longitudinal ends, with a first section (111) and a second section (112), the first section (111) having a narrowing section, the first part (11) comprising a first abutment (115) projecting; - a second part (12) comprising a guide element (124), a flange (120), a second abutment (126), and a second duct (128) extending from a first face of the flange (120), the conduit (128) comprising a third section (122), the guide element (124) comprising at least three lines of contact (129) distributed over a cylindrical surface surrounding the third section (122), the second (112) and third (122) sections having respective mutual coupling means (113, 123). Figure to be published with abstract: Fig. 1

Description

Ventilation device for the interior cooling of a dwelling

The invention relates to the ventilation of a habitat and the heat exchanges between the interior and the exterior of the habitat. The invention relates in particular to ventilation devices intended to be installed in any type of building.

Current ventilation devices exist in different forms that can be classified into two distinct categories:
- electric ventilation devices equipped with a motor which requires an electric power supply to stir the air.
- inert ventilation devices based essentially on the principle of natural ventilation and which therefore do not require electrical energy to operate.

The use of these two types of devices has drawbacks. In most cases, the installation of these ventilation devices requires the help of a competent professional because it can be complex.

Electrical devices cause energy consumption, especially during long-term use. The maintenance of this type of device can also be expensive since it is necessary to maintain the engine in addition to cleaning the air vents. In addition, such maintenance must be carried out by a specialist, which generates additional costs for the user.

The known inert devices do not make it possible to induce cooling and only make it possible to renew the air by creating a flow.

The invention aims to solve one or more of these drawbacks. The invention thus relates to a ventilation device, comprising:

-a first part comprising a first duct extending in a longitudinal direction and having first and second openings at first and second longitudinal ends, the first duct having a first section and a second section between the first and second longitudinal ends, the first section having a section narrowing starting from the first opening towards the second section, the first part further comprising a first stop projecting radially outwards from the first opening, the radial direction being perpendicular to the longitudinal direction;

- a second part comprising a guide element, a flange having a third opening, a second abutment, and a second duct extending in the longitudinal direction from a first face of the flange, the duct comprising a fourth opening at a free end and a third section of cylindrical shape, the guide element extending in the first longitudinal direction from a first face of the flange and comprising at least three lines of contact distributed over a cylindrical surface encircling the third section, the second abutment projecting radially outwards with respect to the guide element, the second and third sections having respective coupling means configured to couple together.

The invention also relates to the following variants. Those skilled in the art will understand that each of the characteristics of the following variants can be combined independently with the characteristics above, without however constituting an intermediate generalization.

According to a variant, the radially projecting part of the first part includes another flange.

According to another variant, the guide element comprises a cylindrical element comprising said three lines of contact.

According to yet another variant, said second conduit has a fourth section connecting the third section to said flange and widening between the third section and said flange.

According to yet another variant, the coupling means include an external thread made on the second section and an internal thread made on the third section.

According to a variant, the length of the thread of the second section is greater than the length of the thread of the third section.

According to yet another variant, said first and second abutments comprise orifices configured to be traversed by fixing screws.

According to a variant, said second stop is a radial extension of said flange.

The invention also relates to an aeration system comprising:

a partition having first and second faces, and comprising an upper bore and a lower bore passing through between the first and second faces;

a first device as defined above, the first and second ducts of which are housed in the upper bore, the first opening being positioned at the level of the first face of the partition;

a second device as defined above, the first and second ducts of which are housed in the lower bore, the first opening being positioned at the level of the second face of the partition.

Other characteristics and advantages of the invention will emerge clearly from the description which is given below, by way of indication and in no way limiting, with reference to the appended drawings, in which:

is a schematic representation of a ventilation device according to a first embodiment of the invention.

is a front view of the first part of a ventilation device according to the first embodiment of the invention.

is a front view of the second part of a ventilation device according to the first embodiment of the invention.

is a sectional view of a ventilation device assembled and housed in a thick wall according to the first embodiment of the invention.

is a sectional view of a ventilation device assembled and housed in a thin wall according to the first embodiment of the invention.

is a sectional view of a ventilation device according to a second embodiment of the invention.

is a perspective view of the second part of a ventilation device according to the first embodiment of the invention.

is a sectional view of a ventilation system housed in a wall according to the first embodiment of the invention.

is a sectional view of a ventilation device including a protective part according to the first embodiment of the invention.

is a perspective view of an example of a protective part of the ventilation device according to the first embodiment of the invention.

is a perspective view of another example of a protective part of the ventilation device according to the first embodiment of the invention.

is a sectional view of a ventilation device according to a third embodiment of the invention.

is a sectional view of a ventilation device assembled and housed in a wall according to the third embodiment of the invention.

Figure 1 is a sectional view of a ventilation device 1 according to the first embodiment of the invention. Ventilation device 1 comprises a first part 11 hereinafter called convergent and a second part 12 having a part complementary to convergent 11. Part 12 will be designated by the term sleeve hereinafter.

The convergent 11 comprises a conduit 117 extending in a longitudinal direction and an abutment 115. The conduit 117 comprises an opening 110 and an opening 114 respectively at the level of the opposite longitudinal ends of the convergent 11 so as to allow a gaseous fluid to circulate.

The conduit 117 comprises a section 111 and a section 112 between its longitudinal ends. Section 111 here extends from opening 110 to section 112. Section 112 here extends between section 111 and opening 114.

The section 111 has a section that narrows between the opening 110 and the section 112 in the longitudinal direction. The section 111 here has a circular section around its longitudinal axis. Section 112 forms a conduit tube 117 from section 111 to opening 114.

The stopper 115 projects outwards from the duct 117, from the first opening 110 in a radial direction perpendicular to the longitudinal direction.

The sleeve 12 includes a flange 120 and a conduit 128. The flange 120 includes an opening 125, here in its middle part. The conduit 128 includes an opening 121 at a free end and extends from a first face of the flange 120 to the opening 121 in the longitudinal direction. Openings 125 and 121 are thus connected by conduit 128 so as to allow a gaseous fluid to circulate.

The conduit 128 forms a section 122 over its entire length. The section 122 forms a wider tube than the section 112 of the convergent 11, so that the section 112 can be inserted into the section 122.

In addition, the sleeve 12 comprises a guide element 124 and an abutment 126. The guide element 124 extends from the first face of the flange 120 in a longitudinal direction while surrounding the section 122. The guide element 124 comprises at least three lines of contact 129 distributed over a cylindrical surface surrounding the section 122, in order to be able to guide the sleeve 12 in a bore made in a partition. The guide element 124 here forms a cylindrical tube extending from the first face of the flange 120 and defining the three lines of contact 129 on its outer surface. The presence of three contact lines on a particular case of cylindrical guide element 124 is illustrated in figure 7.

The stopper 126 projects outwardly from the guide element 124 in the radial direction.

The stops 115 and 126 are used to respectively delimit the stroke of the convergent 11 and the stroke of the sleeve 12 in the longitudinal direction when they are inserted into a bore made in a partition.

The convergent 11 and the sleeve 12 are configured to be coupled and form a flow conduit between two faces of a partition of a housing. The sections 112 and 122 thus have respective threads configured to screw together. These threads thus allow the sections 112 and 122 to join together. These threads also make it possible to define the spacing between the stops 115 and 126, to adjust it to the thickness of the partition.

During the coupling of the convergent 11 and the sleeve 12, the section 112 is here introduced into the middle part of the guide element and into the section 122.

The section 112 is here provided with an external thread 113 and the section 122 is provided with an internal thread 123. The association of the convergent 11 and the sleeve 12 is done more precisely by screwing the section 112 into the section 122. A Appropriate adjustment of the sections 112 and 122 also makes it possible to ensure a seal at the level of their coupling, to avoid a flow of parasitic air at the level of this coupling.

Figure 4 is a sectional view of a ventilation device according to the first embodiment of the invention, assembled and housed in a thick partition 90.

The ventilation device 1 is considered assembled after the mutual screwing of the sections 112 and 122, inserted into a bore of the partition 90. When the sections 112 and 122 are screwed, the conduits 117 and 128 are connected to each other and can therefore a gaseous fluid between the openings 110 and 125.

The geometry of the ducts 117 and 128 thus makes it possible to benefit from the Venturi effect during the circulation of a gaseous fluid between the openings 110 and 125. When a gaseous fluid arrives through the opening 110, it first circulates in the section 111 at a speed V1, at the level of the opening 110. The gaseous fluid then propagates as far as the section 112 and undergoes a depression as the section 111 shrinks itself. Indeed, for the same quantity of material of gaseous fluid, the latter sees its pressure decrease and its speed increase during its passage from the section 111 to the section 112 to keep a constant flow of gaseous fluid. Thus, the velocity V1 of the gaseous fluid at point A is lower than the velocity V2 of the gaseous fluid at a point B in the conduit 128. When the gas reaches the opening 125, the gas has a higher velocity and a pressure and a temperature lower than that at point A. A cooling effect is thus obtained. This cooling effect is achieved without external energy input, unlike air conditioning. Finally, the opening 125 makes it possible to evacuate the cooled gaseous fluid in a room, outside the ventilation device 1.

The ventilation device 1 can be assembled inside a partition 90 if the latter has a bore 903 between its faces 901 and 902. The sleeve 12 can be inserted into the bore 903 on the side of the face 902 of the partition 90. The convergent 11 can be inserted into the bore 903 on the side of the face 901 of the partition 90. The convergent 11 is ideally screwed to the sleeve 12 until the stops 115 and 126 come into contact with the partition 90, in order to to ensure good maintenance of the ventilation device with respect to the partition 90.

The stop 126 is here a radial extension of the flange 120. This extension makes it possible to align the flange 120 and the opening 125 with the face 902 of the partition 90 when the sleeve 12 is completely inserted in the bore 903. This extension of the flange 120 also makes it possible to optimize the seal between the ventilation device 1 and the partition 90, in order to concentrate the flow in the duct 128 and avoid parasitic flows at the periphery of this duct 128.

The projecting part of the convergent 11 here includes another flange 118, forming the abutment 115. Such a flange 118 therefore makes it possible to align the opening 110 with the face 901 of the partition 90 when the convergent 11 is completely inserted into the bore 903. This flange 118 also makes it possible to optimize the seal between the ventilation device 1 and the partition 90, in order to concentrate the flow in the duct 117 and avoid parasitic flows at the periphery of this duct 117.

The stops 115 and 126 comprise orifices 116 and 127 configured to be crossed by fixing screws 9. The fixing screws 9 can then be screwed into the partition 90 so as to fix the ventilation device 1 to the partition 90. In a configuration where the stops 115 and 126 are flanges, several orifices 116 and 127 can be respectively distributed around the openings 110 and 125 respectively.

The length of the thread of the section 112 is advantageously greater than the length of the thread of the section 122. This difference in length makes it possible to have a range of adjustment of the position of the convergent 11 with respect to the sleeve 12 during the screwing of the sections 112 and 122. The distance between the stops 115 and 126 can therefore be adapted to the thickness of the partition 90.

In the case where the partition is thick as shown in Figure 4, the threaded part of the section 122 remains reachable by the threaded part of the section 112. In the case where the wall 90 is thin as shown in Figure 5, a portion of the section 112 may protrude from face 902 of partition 90 after sections 112 and 122 have been screwed. Cutting of this portion of section 112 with suitable tools is then possible outside partition 90. Section 112 can made of synthetic material in order to facilitate easy cutting in such a case.

Figure 6 is a sectional view of a ventilation device 1 according to a second embodiment of the invention. This embodiment differs from the first embodiment only by the structure of the conduit 128. The conduit 128 has another section 1220 connecting the section 122 to the flange 120. The section of the section 1220 widens between section 122 and the flange 120.

This widening of section 1220 forms a divergent. This section 1220 thus makes it possible to limit the turbulence at the outlet of the opening 125, by avoiding too sudden a change in section of the flow.

FIG. 8 is a sectional view of ventilation devices 21 and 22 according to the first embodiment of the invention, housed in a partition 90. The partition 90 has two faces 901 and 902 and comprises an upper bore 903 and a bore lower 904. The bores 903 and 904 pass through the faces 901 and 902 of the partition 90 and are wide enough to pass the ducts 211, 212 and 221, 222 of the ventilation devices 21 and 22 respectively.

The ventilation devices 21 and 22 are positioned head to tail, in order to promote cooling on one side of the partition 90. The ducts 211 and 212 of the ventilation device 21 are housed in the upper bore 903. The opening 213 of the converge of the ventilation device 21 is positioned at the level of the face 901. In this way, a gaseous fluid can circulate from the conduit 211 to the conduit 212 by taking advantage of a flow acceleration by Venturi effect.

-The conduits 221 and 222 of the ventilation device 22 are housed in the lower bore 904. The opening 223 of the convergent of the ventilation device 22 is positioned at the level of the face 902. In this way, a gaseous fluid can circulate from the conduit 221 to conduit 222 by taking advantage of a flow acceleration by Venturi effect, and thus a cooling at the level of the face 901.

Preferably, the partition 90 separates two air media 91 and 92 of different temperatures. The medium 92, being the hottest air medium, is located on the side of the face 902 of the partition 90. The medium 91, being the coldest air medium, is located on the side of the face 901 of the partition 90. The hottest air in the middle 91 tends to rise, then reaches the ventilation device 21, passes through this device 21 to emerge outside towards the middle 92.

Once installed, the ventilation system 2 allows a gaseous fluid from the medium 92 to enter the medium 91 through the ventilation device 22. Similarly, the ventilation system 2 allows a gaseous fluid from the medium 91 to exit in the medium 92 through the ventilation device 21. Consequently, the air in the medium 91 is renewed with the exchanges between the mediums 91 and 92. The medium 91 is also cooled by the phenomenon of natural convection amplified by the flow accelerations taking place within the ventilation devices 21 and 22.

Figure 9 is a sectional view of a ventilation device including a protective part 13 according to the first embodiment of the invention. The protection piece 13 comprises a hermetic membrane 131 and a rim 132. The rim 132 projects outwards from the membrane 131, from the opening in the radial direction, as illustrated in FIG. 132 has holes 133 configured to be crossed by fixing screws 9.

The protective part 13 is intended to be fixed on the convergent 11 and to cover the opening 110, the rim 132 in contact with the stop 115. The opening 110 of the convergent 11 of the device 1 can be closed off by the membrane 131, so as to interrupt the gas flow, for example if the external environment is excessively hot or cold. The rim 132 makes it possible to maintain the protective part 13 fixed to the convergent 11 of the device 1. The orifices 133 and 116 are aligned and are crossed by the same fixing screws 9.

Figure 10 is a perspective view of an example of protection piece 13 for a ventilation device. The membrane 131 is solid and makes it possible to prevent the passage of gaseous fluid through the duct 117 from the opening 110 when the protective part 13 is positioned on the convergent 11.

Figure 11 is a perspective view of another example of protective part 14 of a ventilation device according to the invention. The protective part 14 is identical to the protective part 13, only the membrane 131 being replaced by a mesh 141 of similar shape. The grid 141 is porous to the air and therefore makes it possible to benefit from an air flow if the protective part 14 is positioned on the opening 110 of the converging point of a ventilation device 1. The grid 141, on the other hand, allows to prevent the passage of insects or debris through the conduit 117 when the protective piece 14 is fixed to the convergent 11.

Figure 12 is a sectional view of a ventilation device 1 according to a third embodiment of the invention. The structure of the convergent 11 differs from the first embodiment by the presence of an alternation of shoulders 1130 and grooves on the external surface of the section 112, instead of the thread 113. The shoulders 1130 are spaced from each other in the direction longitudinal (over the entire length of section 112).

Similarly, the structure of the sleeve 12 differs from the first embodiment by the presence of alternating shoulders 1230 and grooves 1231 on the internal surface of the section 122 instead of the thread 123. The shoulders 1230 are spaced between them in the longitudinal direction (over the entire length of the section 122). The grooves 1231 allow the internal surface of the section 122 to follow the contour of the shoulders 1130. The section 122 is preferably elastically deformable, either by the choice of its material, or by appropriate sizing.

Thus, during the coupling of the convergent 11 with the sleeve 12 (as illustrated in FIG. 13), the section 122 is elastically deformed during the passage of the section 112, allowing the shoulders 1130 to be housed in the grooves 1231 between the shoulders 1230. The sections 112 and 122 can thus join together. These shoulders also make it possible to define the spacing between the stops 115 and 126, to adjust it to the thickness of the partition.

To promote the elastic deformation and the coupling between the sections 112 and 122, one or the other of these sections can include a slot extending longitudinally in order to promote the modification of their diameter during the coupling.

Claims (9)

Ventilation device (1), characterized in that it comprises:
-a first part (11) comprising a first conduit (117) extending in a longitudinal direction and having first (110) and second (114) openings at first and second longitudinal ends, the first conduit having a first section (111) and a second section (112) between the first and second longitudinal ends, the first section (111) having a narrowing section starting from the first opening (110) towards the second section (112), the first part ( 11) further comprising a first stop (115) projecting radially outwards from the first opening (110), the radial direction being perpendicular to the longitudinal direction;
- a second part (12) comprising a guide element (124), a flange (120) having a third opening (125), a second stop (126), and a second duct (128) extending in the longitudinal direction from a first face of the flange (120), the conduit (128) comprising a fourth opening (121) at a free end and a third section (122) of cylindrical shape, the guide element (124) extending along the first longitudinal direction from a first face of the flange (120) and comprising at least three lines of contact (129) distributed over a cylindrical surface surrounding the third section (122), the second abutment (126) projecting radially outwards relative to the guide element (124), the second (112) and third (122) sections having respective coupling means (113, 123) configured to couple together. Ventilation device (1) according to claim 1, wherein the radially projecting part of the first part (11) includes another flange (118). A ventilation device (1) according to claim 1 or 2, wherein the guide member (124) comprises a cylindrical member having said three lines of contact (129). Ventilation device (1) according to any one of the preceding claims, in which the said second duct (128) has a fourth section (1220) connecting the third section (122) to the said flange (120) and widening between the third section (122) and said flange (120). Ventilation device (1) according to any one of the preceding claims, in which the coupling means include an external thread (113) provided on the second section (112) and an internal thread (123) provided on the third section ( 122). Ventilation device (1) according to claim 5, in which the length of the thread of the second section (112) is greater than the length of the thread of the third section (122). Ventilation device (1) according to any one of the preceding claims, in which the said first (115) and second (126) stops comprise orifices (116 and 127) configured to be traversed by fixing screws (9). Ventilation device (1) according to any one of the preceding claims, in which said second abutment (126) is a radial extension of said flange (120). Aeration system (2) comprising:
-a partition (90) having first (901) and second (902) faces, and comprising an upper bore (903) and a lower bore (904) passing through between the first (901) and second (902) faces;
-a first device (21) according to any one of the preceding claims, the first (211) and second (212) ducts of which are housed in the upper bore (903), the first opening (213) being positioned at the level of the first face (901) of the partition;
- a second device (22) according to any one of the preceding claims, the first (221) and second (222) ducts of which are housed in the lower bore (904), the first opening (223) being positioned at the level of the second face (902) of the partition.