EP0972991A1 - Static/dynamic gas extraction device - Google Patents

Abstract

The invention relates to a mixed, static / dynamic device (1) for discharging gaseous fluid, comprising on the one hand an upper element (2) and on the other hand a lower element (3), superimposed, coaxial, rigidly fixed to each other by connecting spacers (4). The device (1) further comprises an axial cavity 25) open towards a space (8) housing the blades (24) of a centrifugal turbine with rotor (26) and stator (23) located in the axial cavity (25). <IMAGE>

Description

The invention relates to a device for the evacuation of gaseous fluid, in particular of exhaust gases or smoke.

We already know static devices for the rejection of gaseous fluids, intended to be mounted on buildings. Such devices are for example of the type comprising a lower element, upper element, spacers to rigidly hold the two coaxial elements spaced from each other so as to define between them a passage, and a conduit passing through the lower element and opening into the passage.

The lower and upper elements are limited by conical or frustoconical side walls, so that said passage has, in axial section, a general shape of venturi or convergent / divergent, along a direction radial orthogonal to the general axis of the device. This axis is generally at least substantially vertical. Such device is usually mounted above the roof of the building for which it is intended. The conduit allows to collect and channel the gases or fumes, which come out of this led by its upper end generally located at the upper limit of the lower element, where even the passage in the form of a venturi. The gas fluid or smoke is then diverted and entrained in this passage towards the exterior of the device and the exterior atmosphere. The presence of wind accelerates this process. Such a device is described, for example, in document FR-A-1 403 955.

Such a static device is generally arranged in height and is therefore susceptible to winds ascending or plunging winds or winds horizontal. In the absence of wind, only the thermal draft residual, based on the physical phenomenon taking place in all vertical duct, remains the only upward motor. this residual thermal draft is calculated by the formula Dp = 0.046 H (Dt) where Dp is the depression in Pascals created in the flue, H is the height of the chimney, and Dt is the difference between the outside temperature and interior. In fact during periods of outside temperature approximating the interior temperature, the driving effect upward in the absence of wind will be almost zero.

To overcome these drawbacks, one solution is to use a mixed motorized system, the motor being able to be activated by a programmed clock or probe systems pressure, hygrometric, or other.

Documents EP-A-0 416 999 and FR-A-2 709 534 concern static devices as described above further comprising a centrifugal turbine having a motor arranged in the upper element and at least one blade arranged in the free space between the upper element and inferior. Such dynamic devices allow significantly improve the evacuation of gases or fumes rejected by rotation of the blade in the form space general convergent / divergent or venturi.

In the systems proposed in these documents, the part mechanical includes several radial blades mounted by example on a hub coming to take place at one of the ends of the shaft of a traditional motor.

These systems have drawbacks, however.

A first drawback is the adjustment of the balancing of the system over time, due to the significant overhang caused by the turbine with the radial blades.

Another disadvantage is the premature wear of the bearings of the motor shaft, due to the turbine placed at the end and suspended from the motor shaft.

In addition, the positioning of the motor in the element metal upper part of the device, in addition to the volume important that it occupies, has the disadvantage of generating relatively significant noise pollution, by effect sound box.

The invention aims to propose a device of the general type described in document FR-A- 2 709 534, including balancing and wear resistance are improved, the operation of the device also generating a level lower noise than prior art systems.

To this end, according to a first aspect, the invention proposes a static / dynamic device for the evacuation of gaseous fluid, in particular of exhaust gases or fumes, comprising an upper element and a lower element, superimposed, coaxial, rigidly fixed to each other by connecting spacers.

The lower element includes a lower bottom and a lower cap, coaxially crossed by a pipe given diameter d opening at one of its ends, side lower hat, in the space between the two elements, the other end being fixed to the arrival of gaseous fluids.

The bottom bottom and the bottom cap are rigidly fixed to each other by their large common base.

The top element includes a top cap and a upper bottom. They are rigidly fixed to each other by their large common base.

The device further comprises a centrifugal turbine comprising a motor and at least one blade.

The upper bottom has an axial cavity open towards the space housing the blades.

According to the invention, the motor comprises a stator located at the interior of the axial cavity and a rotor, provided with minus one blade, located in the axial cavity, the motor being devoid of motor shaft.

Thus, according to the invention, the upper cap of the element upper is tall, especially tall, reduced compared to the systems of the prior art.

The absence of a motor shaft also makes it possible to avoid wear phenomena, especially bearings, and phenomena of imbalance of the balancing of the device.

According to other characteristics, the blades have an edge lower radial flush with the lower base of the cavity axial.

The axial cavity has a frustoconical shape coaxial at top hat, large space side base and small closed base.

According to one embodiment, the cavity projects in part from the upper bottom of the upper element towards space.

It is also conceivable that the large base of the cavity is arranged substantially in the same plane as the upper bottom of the upper element, the cavity being then integrated inside the upper element.

Or that the small base of the cavity is substantially in the same plane as the upper bottom of the upper element, the cavity then being placed outside the element superior.

The cavity can also occupy an intermediate position between a position inside the element upper and a position located outside the element superior.

According to another aspect of the invention, the device presents dimensional functions of the diameter pipe able to optimize the aerodynamic qualities of the device.

• la figure 1 est une vue schématique, en coupe verticale diamétrale d'un mode de réalisation du dispositif selon la présente invention ;
• la figure 2 est la même vue schématique que la figure 1 présentant des références dimensionnelles ;
• la figure 3 est une représentation schématique, vue de dessus, du chapeau inférieur du dispositif de la figure 1 ;
• la figure 4 est une vue de détail d'une partie du dispositif avec éléments de pales mobiles ;
• la figure 5 est une vue schématique, de côté, d'une première turbine centrifuge utilisée dans le dispositif de l'invention ;
• la figure 6 est une vue schématique, en coupe verticale diamétrale, d'un autre mode de réalisation du dispositif de l'invention ;
• la figure 7 est une vue schématique, de côté, d'une autre turbine centrifuge utilisée dans le dispositif de l'invention.

The invention will be described in more detail with reference to the accompanying drawings in which:

• Figure 1 is a schematic view, in diametrical vertical section of an embodiment of the device according to the present invention;
• Figure 2 is the same schematic view as Figure 1 showing dimensional references;
• Figure 3 is a schematic representation, seen from above, of the lower cap of the device of Figure 1;
• Figure 4 is a detail view of part of the device with movable blade elements;
• Figure 5 is a schematic side view of a first centrifugal turbine used in the device of the invention;
• Figure 6 is a schematic view, in diametrical vertical section, of another embodiment of the device of the invention;
• Figure 7 is a schematic side view of another centrifugal turbine used in the device of the invention.

The invention relates to a static / dynamic device for rejection of gases or fumes. Such devices are intended in particular to be mounted on chimneys evacuation of gaseous fluid arranged on buildings to residential, or commercial, or industrial use.

Such a device 1 generally has an axis 100 which, when the device is mounted on the chimney, is the more often vertical or close to vertical. Through convention and for reasons of simplification and better understanding, the description is more particularly made in relation to positions climbs which correspond to those presented on the Figures 1, 2 and 6. The qualifiers of superior, lower, etc. should be understood in connection with this mounted position. Likewise, the axial qualifiers, transverse, etc. must be understood in relation to axis 100.

The axis 100 is preferably an axis of revolution. It is in this variant that the description is made which follows. However, in other embodiments, the axis 100 is only symmetrical or even only defines the general management of the system 1.

The device 1 comprises a lower element 3, an element higher 2; 4 association bodies in the form spacers of the lower 3 and upper 2 elements of way that they are spaced coaxially and opposite one on the other, which gives them a free passage 8 for gases or fumes.

The free passage 8 in axial cross section has a shape general in convergent / divergent. The device includes in addition to a conduit 7 for gases or fumes passing through the lower element 3 and opening through its downstream opening 15 in passage 8 (the qualifier "downstream" means by relation to the normal direction of gas or smoke circulation when rejected by the device).

The duct 7 has a certain axial length. He is destined to be connected to the chimney by means of flanges or other.

The device finally comprises a centrifugal impeller with blades radial.

In a typical form shown in Figure 1, but not limiting, the lower element 3 comprises a bottom 5 lower and a lower hat 6, each shaped general frustoconical. Bottom 5 and hat lower 6 are crossed coaxially by the pipe 7 having a given diameter d. Pipe 7 leads to one of its ends 15, bottom hat side 6, in space 8 between the two elements 2, 3. The other end of the pipe 7 is fixed to the inlet of the gaseous fluid, namely the fireplace. In the embodiment shown in the Figures 1 and 2, the pipe 7 has at its side end space 8 a radial annular projection 22 on which comes to lock in abutment the small base of the hat lower 6.

The bottom bottom 5 and the bottom cap 6 are rigidly fixed to each other. The lower cap 6 is provided with an annular lip 10, adjoining a large common base 9, directed downward from said large base 9 and in line with the surface of the lower hat 6. The lower bottom 5 includes a peripheral crown 20 parallel to the frustoconical surface of the lower cap 6. The annular lip 10 comes in direct extension of the frustoconical surface of the hat lower 6 and the connecting spacers 4 rest on the frustoconical surface of the lower cap 6.

In order to rest the spacers 4 on the surface frustoconical of the lower cap 6, each of the spacers 4 can, for example, be provided at its end lower, of a lower connecting tab 21 (figure 3). In a spacer service position, this lower tab 21 is parallel to, and in contact with and secured to the frustoconical surface of the lower cap 6 and extends in a tangential direction.

In one embodiment of the invention, the tab lower link 21 can be in one piece with the spacer, in another embodiment of the invention the lower leg 21 can be added to the end of the spacer 4.

Another solution not shown is to bring out the spacers 4 of the frustoconical surface of the hat lower 6.

In order to achieve the emergence of spacers 4 of the frustoconical surface of the lower cap 6, the cap lower 6 includes in its frustoconical surface axial peripheral bosses intended to receive the end of the lower element side 3 of the spacers 4. A this effect, each boss comprises a transverse base in look of a transverse flat of the peripheral crown 20 of the lower bottom 5. Together they define a base transverse mounting and securing of the end lower element side 3 of a spacer 4 on the element lower 3. Thus the lower end of the spacers is somehow immersed in the frustoconical surface of the lower cap 6 so that externally, the spacer appears emerged from said frustoconical surface.

Also in a typical form shown in the figure 1, the upper element 2 comprises an upper cap 12 and an upper bottom 11. They are rigidly fixed one to the other by a large common base 13. The upper bottom 11 and the upper cap 12 each include a transverse peripheral crown 18, 19 opposite. These transverse peripheral rings 18, 19 define a transverse mounting and joining strip the end of the upper element side 2 of the spacers 4 on the upper element 2. For this purpose each spacer 4 may, for example, have an upper tab of link, parallel to the transverse strip and extending in a tangential direction. The two forms of realization cited for the lower leg 21 are also applicable for the upper leg.

The mounting of the upper base 11 and the upper cap 12 on the end, upper element side 2, spacers 4 can also be achieved, without day, by joining together the ends, on the side of the spacers 4, of the cap upper 12 and upper bottom 11.

The upper cap 12 can also be provided with a peripheral annular lip 14, adjoining the large base 13, directed downward from the large base and into the extension of the surface of the upper cap 12.

This peripheral annular lip 14 comes in extension of the peripheral crown 18 of the upper cap 12 and covering the peripheral ring 19 of the bottom higher 11.

The transverse peripheral rings 18 and 19 in look respectively are an extension of the large base of the first truncated cone 33 of the upper bottom 11 and in extension of the large base of the second truncated cone 32 upper cap 12.

In the embodiment shown in Figures 1 and 2, the upper bottom 11 has an axial cavity 25 open to space 8 housing the blades 24 of a turbine centrifugal. Depending on the embodiment shown, the blades 24 have a lower radial edge 27 flush with the base 28 lower of the axial cavity 25. The centrifugal turbine includes a stator 23 housed inside the cavity axial 25 and a rotor 26 also housed inside the axial cavity 25. The rotor 26 carries the radial blades 24, for example two, three, four or five.

In the embodiment shown in Figure I, the upper cap 12 includes a 3G conical cap extended by its large base and coaxially by a first truncated cone 31, of reduced size, having its small common base with the large base of the cap 30.

The first truncated cone 31 is itself extended coaxially by a second truncated cone 32 having its small common base with the large base of the first trunk of cone 31.

According to another embodiment, the upper cap 12 includes a single conical cap - replacing the cone trunks 31 and 32- whose large base is common with the upper bottom 11.

According to this embodiment, the frustoconical surface of the conical cap made for example with its large base a angle of the order of 22 °.

Still according to the embodiment shown in the Figure 1, the upper bottom 11 comprises a first trunk of cone 33 coaxial to upper cap 12 small base 17 space side 8. The small base 17 is suitable for accommodate the cavity or a cavity element 25 intended to house the blades 24.

Advantageously, the cavity 25 has a frustoconical shape coaxial with the upper cap 12 and includes a large base 28 on the space side 8 and a small base 29 closed on the side top hat 12.

In the embodiment shown in Figure 1, the cavity element 25 projects in part from the upper bottom 11, in particular of the small base 17 of the first trunk of cone 33, towards space 8.

Finally, always with the aim of improving the performance of the device, the cavity or the cavity element 25 can be advantageously provided with an adjoining annular lip 34 at the peripheral base 28 and directed upwards.

According to one embodiment, the small base 15 of the hat lower 6 includes an annular projection 16 of direction axial and height h. In one embodiment, this axial annular projection 16 can be produced by the end 15 of the pipe 7 protruding from the small base of the lower cap 6 to space 8.

In the description which follows, it will be mentioned the dimensional characteristics of the constituent elements of the device according to the embodiment shown in Figures 1 and 2 and given by way of example not limiting. These dimensional characteristics will be generally related to the diameter d of the pipe 7. These dimensional characteristics are important in the to the extent that they make it possible to produce a device considerably improving the evacuation qualities of gaseous fluid regardless of the wind direction and the operating mode. You will find at the end of this description a summary table of said dimensional characteristics.

Advantageously, the device 1 according to the invention is such that the maximum diameter D of the upper element 2 is substantially equal to the maximum diameter of the element lower 3.

The dimensional ratio D / d is advantageously understood between 1.5 and 3. The dimensional ratio D / d is preferably substantially equal to 2.25.

The dimensional ratio h / d (h being the height of the annular projection 16) is advantageously between 0.01 and 0.15. The dimensional ratio h / d is preferably substantially equal to 0.08.

Let H be the minimum distance separating the two elements upper and lower (i.e. in the embodiment shown in Figure 2, the distance separating the end 15 of the large base 28 from the element 25), the dimensional ratio H / d is advantageously between 0.25 and 1.2. The report dimensional H / d is preferably substantially equal to 0.7.

Let be the angle a made by the frustoconical surface of the hat lower 6 with the large base 9, the angle a is advantageously between 15 ° and 45 ° and preferably substantially equal to 30 °.

Let the angle b made by the tapered surface of the bottom lower 5 with the large base 9 and the angle g made by the frustoconical surface of the second truncated cone 32 of the cap upper 12 with its large base, angles b and g are advantageously between 0 ° and 30 ° and preferably equal to 22 °.

Let the angle d made by the surface of the first truncated cone 33 of the upper bottom 11 with the large base 13, the angle d is advantageously between 0 ° and 30 ° and preferably substantially equal to 22 °.

Let d _{2 be} the diameter of the small closed base 29 of the cavity 25, the dimensional ratio d ₂ / d is advantageously between 0.8 and 2 and preferably substantially equal to 1.12.

Let d _{3 be} the diameter of the large open base 28 of the cavity 25, the dimensional ratio d ₃ / d is advantageously between 1 and 2.40 and preferably substantially equal to 1.31.

Let d4 be the axial height of the axial cavity 25, the dimensional ratio d ₄ / d is advantageously between 0.2 and 0.5 and preferably substantially equal to 0.28.

The cavity 25 projects from the small base 17 of the first truncated cone 33 from the upper bottom 11 to the space 8, with a value between half and all of its axial height d ₄ .

Preferably, the projecting part of the cavity 25 is substantially equal to 0.18 x d.

Let the angle m made by the frustoconical surface of the cavity 25 with its large base 28, the angle m is advantageously between 45 ° and 90 ° and preferably substantially equal to 75 °.

The frustoconical surface of the first truncated cone 31 of the upper cap 12 makes an angle of the order of 60 ° more or less 10 ° with its large base.

The conical surface of the conical cap 30 of the hat upper 12 advantageously makes an angle of the order of 12 ° more or less 5 ° with its large base.

The distance between the small closed base 29 of the cavity 25 from the top of the conical cap 30 is advantageously and preferably of the order of 0.8 x d.

The annular lip 34 adjoining the base 28 forms an angle of the order of 22 ° plus or minus 10 ° with the base 28 and a a width of the order of 0.1 x d.

In the embodiment shown in the figures, the device comprises at least two, in particular three connecting struts 4 arranged every 120 ° at its periphery. the spacers 4 are flat in shape with rounded edges, of radial length t ₃ and of width e ₃ . The dimensional ratio t ₃ / d is advantageously between 0.04 and 0.07 and preferably substantially equal to 0.05. The dimensional ratio e ₃ / t ₃ is advantageously between 0.02 and 0.5.

According to another embodiment, the spacers 4 have over most of their axial length - along axis 100 - a boss, arranged substantially at center of the spacers 4 and substantially parallel to axis 100.

The region of the spacers 4 located on either side of this boss can then be reduced in thickness and not consist than a thin plate.

Let be the angle 1 made by the annular lips 10,14 with respectively the large bases 9, 13, the angle l is advantageously between 45 ° and 70 ° and preferably substantially equal to 60 °.

The transverse peripheral rings 18 defining the transverse mounting and securing band of the end of the upper element side 2 of the spacers on the upper element 2 have a radial width substantially equal to the radial length t _{3 of} said spacers 4.

The device according to the invention may further comprise a mesh element (not shown), of cylindrical shape coaxial with, and extending between the upper 2 and lower elements 3. This mesh element of cylindrical shape has a diameter at least greater than the diameter d ₃ of the large open base 29 of the cavity 25 increased by the annular crown 34. Preferably, this mesh element comprises meshes of 20 mm x 20 mm to more or less 2mm.

Referring now to Figure 6, the element lower 3 comprises a part 44 of general shape frustoconical whose small base 45, upper, where is finds the space 8, is turned towards the upper element 2 while the large base 46, lower, faces the opposite of the upper element 2.

The diameter of the large base 46 is of the order of 1.6 to 2.5 times the diameter of the small base 45.

The lower element 3 is placed opposite the element upper 2, being removed from the latter, the elements upper (2) and lower (3) being secured one with the other by means of spacers 4.

These spacers extend substantially parallel to axis 100.

The small base 45 of the lower element 3 can be surmounted by a lip 47, of section substantially circular.

The height of the lip 47 -counted parallel to the axis 100- is around 0.01 to 0.02 times the diameter of the small base 45.

In addition, the height -counted along the axis 100- between the free peripheral edge of lip 47 and upper bottom 11 is of the order of 0.45 to 0.8 times the diameter of the small base 45.

The upper bottom 11 of the upper element 2 is presented in the form of a flattened cup 48. This cup 48 is generally circular in shape.

The cup 48 includes a central part 49, transverse, axially offset from the part remaining annular outer 50.

The outside diameter of the cup 48 is equal or close the outside diameter of the lower element 3 defined by the large base 9.

The diameter of the central part 49 is equal to or close to the diameter of the open space 8. It is, in the modes of represented achievement, between 0.8 and 1.25 times the diameter of the small base 45.

The diameter of the central part 49 is, in the achievement considered, between 0.4 and 0.6 times approximately the outside diameter of the cup 48.

In particular, the diameter of the central part 49 is the order of half the outside diameter of the cup 48.

The axial offset of the central part 49 relative to the annular outer part 50 - along axis 100 - is the order of a tenth of the diameter of the central part 49, and preferably of the order of 0.15 to 0.5 times the diameter of the small base 45.

The central transverse part 49 is flat or substantially flat, as is the exterior ring finger 50.

The central part 49 is connected to the external part 50 by a connecting wall 51 of general shape frustoconical, inclined relative to the axis 100.

The small diameter of this connecting wall 51 is located on the side of the central part 49 and its large diameter of the side of the annular outer part 50.

The angle of inclination of the connecting wall 51 on axis 100 is between 15 ° and 45 °.

In the embodiment shown in Figure 6, this angle is around 20 °.

The cup 48 comprises in the embodiment shown, a outer edge 52 falling towards a transverse median plane, passing through the middle part of the lower element 3.

The axial length of the falling outer edge 52 is the order of one third or two thirds of the axial offset of the central part 49 relative to the external part ring finger 50.

The angle of inclination of the outer edge falling 52 on axis 100 can be of the same order of magnitude as that of the connection wall 51.

The cavity 25 formed by the central part 49 and the wall connection 51 allows the housing of a turbine, represented schematically by the reference 53, fixed to the cup 48.

The upper element 2 comprises a protective cover 54.

This protective cover 54 is fixed to the cup 48, of the side opposite the lower element 3.

Such a cover 54 has a generally conical shape or frustoconical with, in the latter case, a wall upper transverse 55.

Such a cover 54 can be fixed to the external part annular 50 in the vicinity of the falling edge 52. An opening 56 can be provided between the cover 54 and the part outer annular 50 so as to allow the air circulation inside the cover 54.

According to another embodiment (not shown), the cover 54 can be fixed on the connection wall 51, optionally by providing an opening between the cover 54 and the wall 51.

According to yet another embodiment (not shown), the cover 54 can be fixed on the central part 49, optionally by providing an opening between the cover 54 and the central part 49, by means of pads substantially parallel to axis 100.

In this alternative embodiment, the cover 54 does not occupy the entire surface of the dish 48.

Furthermore, in the embodiment shown, where the cover 54 is of generally frustoconical shape, to improve air circulation, and therefore cooling the turbine 53, an opening 57 is provided in the upper wall 55 of the cover 54.

The wall 55 is surmounted by a cap 58, of shape general conical. The base 59 of the hat 58 is fixed to the wall 55 with a space 60 between them for the evacuation of air from opening 57.

In the embodiments shown in FIGS. 1, 2 and 6, the cavity 25 projects in part from the small base 17 from the first truncated cone 33 from the upper bottom 11 towards space 8.

The large base 28 of the cavity 25 can also be arranged substantially in the same horizontal plane as the upper bottom 11 -or, in the embodiment of the Figure 6 of the cup 48- of the upper element 2, the cavity 25 being in this case fully integrated in the upper element 2.

It is also conceivable that the small base 29 of the cavity 25 is substantially in the same plane as the bottom upper 11 -or that the cup 48- of the upper element 2, the cavity 25 then being placed outside of the upper element 2.

The intermediate positions between the two positions above are also possible.

Referring now more particularly to the figure 5, the device according to the invention comprises a turbine centrifugal comprising a stator 23 provided on one of its faces of a conventional fastening means 42 in itself.

This means 42 is intended for fixing the turbine in the axial cavity 25.

The centrifugal turbine also includes a rotor 26 on which is mounted, on the side of the stator 23, a flange 40 allowing the blades 24 to be fixed by means 41 classic in itself, for example screwing.

The turbine comprises, on the stator 23 side, means for electrical connection 43 connected to a command (not shown) to activate or deactivate it turbine operation.

The distal 35 and upper radial 36 edges of the blades 24, mounted via the flange 40, can advantageously match the surface of the cavity 25.

According to another embodiment shown in the figure 7, the rotor 26 is provided with at least one fixing part blades 24, replacing the flange 40 of FIG. 5.

This fixing piece is fixed to the rotor 26, by example by a screw 62, positioned along the axis of rotation of the rotor 26. The fixing part consists for example of an oblong bar 61 conforming substantially to the shape external of the rotor 26 on either side of the screw 62 and is extending towards the stator 23.

At each end of the bar 61, a blade 24 is fixed, for example by screwing, directly or by means of a plate 63 added.

Depending on the number of blades 24 desired, one or more can be provided multiple bars 61.

According to another embodiment (not shown), the fixing part consists of a hollow cap covering the rotor 26 being fixed thereon by a screw positioned along the axis of rotation of the rotor 26.

On the hollow cap are fixed, by conventional means in itself, one or more blades 24.

In one embodiment of the invention (FIG. 4), the lower radial edges 27 of the blades 24 are extended by blade elements 37 articulated in rotation around of said radial edges 27. This rotation is ensured by one or more hinges 39. These blade elements 37 are articulated in rotation between a first position at rest where the blade elements 37 are substantially perpendicular to the blades 24 when the turbine is not activated, and a second active position where each element blade 37 is substantially in the same plane as the blade 24 associated when the turbine is activated.

Advantageously, the blade elements 37 are forced into the rest position by an elastic element 38. The transition from the rest position to the active position is due to the inertial and centrifugal forces induced by the rotation imparted by the turbine to the blades 24 and to the blade elements 37. In the embodiment particular shown in the figures, the device according to the invention comprises two large blades 24 crossing on axis 100 so as to create four half-blades. In addition, the two blades 24 intersect at an angle law.

In the representation of FIG. 4, each half-blade includes a blade element 37 in a quarter circle. Of this so, in the rest position, the blade elements 37 are perpendicular to the half-blades and form in combination a cover closing the lower base 28 of the cavity 25. In this way, in the rest position, that is to say when the engine is not activated, the performance of the device are not disturbed by the presence of blades 24, these being masked by the blade elements 37.

Although only certain embodiments of the invention have been described, it is obvious that any modification made in the same spirit by a person skilled in the art would not depart from the scope of the present invention. The dimensions or the dimensional ratios indicated are given by way of nonlimiting example. The number of blades or half-blades can vary without departing from the scope of the present invention. The shape and number of blade elements can also vary without departing from the scope of the present invention. FORK PREFERRED VALUE D / d 1.5 - 3 2.25 m / d 0.01 - 0.15 0.08 M / d 0.25 - 1.2 0.7 d ₂ / d 0.8 - 2 1.12 d3 / d 1 - 2.40 1.31 d4 / d 0.2 - 0.5 0.28 t ₃ / d 0.04 - 0.07 0.05 e ₃ / t ₃ 0.02 -0.5 / at 15 ° - 45 ° 30 ° b 0 ° - 30 ° 22 ° g 0 ° - 30 ° 22 ° d 0 ° - 30 ° 22 ° l 45 ° - 70 ° 60 ° m 45 ° - 90 ° 75 °

Claims (34)

Device (1) mixed, static / dynamic for the evacuation of gaseous fluid, in particular of rejected gases or fumes comprising on the one hand an upper element (2) and a lower element (3), superimposed, coaxial, rigidly fixed l 'to one another by connecting spacers (4), the lower element comprising a bottom (5) lower and a cap (6) lower, crossed coaxially by a pipe (7) of given diameter d leading to the one of its ends, lower cap side (6), in the space (8) between the two elements (2, 3), the other end of the pipe (7) being intended to be fixed to the inlet of the fluids gaseous, said lower bottom (5) and said lower cap (6) being rigidly fixed to each other by their large common base (9); the upper element (2) comprising an upper bottom (11) and an upper cap (12); and on the other hand a centrifugal turbine comprising a motor and at least one blade (24),
the upper bottom (11) having an axial cavity (25) open towards the space (8) housing the blades (24), the motor comprising a stator (23) located inside the axial cavity (25) and a rotor (26) provided with at least one blade (24), located in the axial cavity (25), the motor being devoid of motor shaft. Device according to claim 1, characterized in that that the cavity (25) has a frustoconical shape coaxial with top hat (12), large base (28) space side (8), small base (29) closed. Device according to claim 1 or 2, characterized in that the cavity (25) projects in part from the upper bottom (11) from the upper element (2) to the space (8). Device according to claim 1 or 2, characterized in that the large base (28) of the cavity (25) is disposed substantially in the same plane as the upper bottom (11) of the upper element (2), the cavity (25) then being integrated inside the upper element (2), or the small base (29) of the cavity (25) is substantially in the same plane as the upper bottom (11) of the upper element (2), the cavity (25) then being placed outside of the upper element (2). Device according to claim 1 or 2, characterized in that the cavity (25) occupies an intermediate position between a position inside the element upper (2) and a position located outside of the upper element (2). Device according to any one of claims 1 to 5, characterized in that the blades (24) have a radial edge (27) lower flush with the lower base (28) of the axial cavity (25). Device according to any one of claims 1 to 6, characterized in that the upper cap (12) comprises a conical cap (30), the large base of the cap conical (30) being extended coaxially by a first truncated cone (31), small, small base common with the large base of the cap (30), the first truncated cone (31) being itself extended coaxially by a second truncated cone (32) of small common base with the large base of the first truncated cone (31). Device according to any one of claims 1 to 7, characterized in that the upper bottom (11) comprises a first truncated cone (33) coaxial with the upper cap (12) of small base (17) space side (8), said small base (17) being adapted to accommodate the cavity (25) intended to house the blades (24). Device according to any one of claims 1 to 8, characterized in that the upper cap (12) is provided with an annular lip (14), peripheral, directed down from the large base (13) and into the extension of the surface of the upper cap (12). Device according to any one of claims 1 to 9, characterized in that the upper bottom (11) and the upper cap (12) each include a crown transverse peripheral (18, 19) opposite, defining a transverse mounting and joining strip the end of the upper element side (2) of the spacers (4) on said upper element (2), the annular lip (14) extending from the peripheral crown (18) of the upper cap (12) and overlapping the crown peripheral (19) of the upper bottom (11), the crowns transverse peripherals (18, 19) opposite coming respectively in extension of the large base of the first truncated cone (33) of the upper bottom (11) and extension of the large base of the second truncated cone (32) of the upper cap (12). Device according to any one of claims 1 to 10, characterized in that the upper cap (12) includes a single conical cap with a large base common with the upper bottom (11), the frustoconical surface of the single conical cap making for example with its large base an angle of about 22 °. Device according to any one of claims 1 to 6, characterized in that the upper element (2) comprises an upper bottom (11) in the form of a flattened cup (48), generally circular in shape, the cup (48) comprising a central part (49), transverse, axially offset from the part remaining annular outer (50), the central part (49) being planar or substantially planar and being connected to the annular outer part (50) by a wall of connection (51) of generally frustoconical shape. Device according to any one of claims 1 11, characterized in that the lower bottom (15) and the lower caps (6) are each of frustoconical shape and in that the lower cap (6) is provided with a lip annular (10), adjoining the large common base (9), directed downwards from the large common base (9) and in the extension of the surface of the lower hat (6). Device according to claim 13, characterized in that that the lower bottom (5) comprises a crown peripheral (20) parallel to the frustoconical surface of the lower cap (6). Device according to any one of claims 1 to 6 and 12, characterized in that the lower element (3) comprises a part (44) of generally frustoconical shape, the small upper base (45) faces the element upper (2), while the lower large base (46), faces the opposite of the upper element (2). Device according to claim 15, characterized in that that the small base (45) is surmounted by a lip (47) of substantially circular section. Device according to any one of claims 1 to 16, characterized in that each of the spacers (4) in service position includes at its lower end a lower connecting lug (21) parallel to, and to contact, and integral with the frustoconical surface of the hat lower (6), and extending in one direction tangential to the axis (100) of the device. Device according to claim 17, characterized in that that the spacers (4) comprise over the major part of their axial length - following the axis (100) - a boss, arranged substantially in the center of the spacers (4) and substantially parallel to the axis (100), the region of spacers (4) located on either side of the boss being reduced thickness. Device according to any one of claims 1 to 18, characterized in that the lower cap (6) includes, at its small base (15), a projection annular (16) of axial direction and height h, the dimensional ratio h / d being between 0.01 and 0.15 and preferably substantially equal to 0.08 and / or that the angle 1 made by the annular lips (10, 14) with the large bases (9, 13) is between 45 ° and 70 ° and preferably substantially equal to 60 °. Device according to any one of claims 1 to 19, characterized in that the maximum diameter D of the upper element (2) is substantially equal to the diameter maximum of the lower element (3), and in that the ratio dimensional D / d is between 1.5 and 3 and preferably substantially equal to 2.25. Device according to any one of claims 1 to 20, characterized in that H being the minimum distance separating the two upper (2) and lower (3) elements, the dimensional ratio H / d is between 0.25 and 1.2 and preferably substantially equal to 0.7. Device according to any one of claims 1 to 21, characterized in that the angle a made by the surface frustoconical of the lower cap (6) with its large base (9) is between 15 ° and 45 ° and preferably substantially equal to 30 °. Device according to any one of claims 1 to 22, characterized in that the angle b and / or the angle g and / or the angle d that the surface respectively make frustoconical of the lower bottom (5), the frustoconical surface of the second trunk of cone (32), the surface of the first trunk cone (33) of the upper bottom (11) with their large base respective is / are between 0 ° and 30 ° and preferably substantially equal to / equal to 22 °. Device according to any one of claims 1 to 23, characterized in that d ₂ being the diameter of the small closed base (29) of the cavity (25), the dimensional ratio d ₂ / d is between 0.8 and 2 and preferably substantially equal to 1.12 and / or in that d ₃ being the diameter of the large open base (28) of the cavity (25), the dimensional ratio d ₃ / d is between 1 and 2.40 and preferably substantially equal to 1.31 and / or in that d ₄ being the axial height of the axial cavity (25), the dimensional ratio d ₄ / d is between 0.2 and 0.5 and preferably substantially equal to 0.28. Device according to any one of claims 1 to 24, characterized in that the cavity (25) protrudes from the small base (17) towards the space (8) between the half and the its entire axial height and preferably protrudes by a distance substantially equal to 0.18 x d, and in that the angle m made by the frustoconical surface of the cavity (25) with its large base (28) is between 45 ° and 90 ° and preferably substantially equal to 75 °. Device according to any one of claims 7 to 25, characterized in that the frustoconical surface of the first truncated cone (31) of the upper cap (12) made an angle of around 60 ° plus or minus 10 ° with its large base, and / or in that the conical surface of the cap conical (30) makes an angle of about 12 ° more or less 5 ° with its large base. Device according to any one of claims 1 to 26, characterized in that the distance between the small closed base (29) of the cavity (25) of the top of the cap conical (30) is of the order of 0.8 x d. Device according to any one of claims 1 to 27, characterized in that the axial cavity (25) is provided with an annular lip (34) adjoining the base (28), peripheral and directed upwards at an angle of the order of 22 ° plus or minus 10 ° with the base (28) and having a width of the order of 0.1 d. Device according to any one of Claims 1 to 28, characterized in that it comprises at least two spacers (4) arranged at the periphery of the device, the spacers (4) being of flat shape with rounded edges, of radial length t ₃ and of thickness e ₃ , the dimensional ratio t ₃ / d being between 0.04 and 0.07 and preferably substantially equal to 0.05, and the dimensional ratio e ₃ / t ₃ being between 0.02 and 0.5. Device according to any one of claims 1 to 29, characterized in that the turbine includes a stator (23) provided on one of its faces with a fixing means (42), the turbine further comprising a rotor (26) on which is mounted, on the side of the stator (23), a flange (40) allowing the attachment of the blades (24). Device according to any one of claims 1 to 29, characterized in that the rotor (26) is provided with least one blade attachment piece (24), fixed on the rotor (26), for example by a screw (62) positioned according to the axis of rotation of the rotor (26); the fixing piece consisting of an oblong bar (61) substantially matching the external shape of the rotor (26) on either side of the screw (62) and extending towards the stator (23), a blade (24) being attached to each end of the bar (61), or the fastener consisting of a hollow cap covering the rotor (26) by being fixed thereon by a screw positioned along the axis of rotation of the rotor (26), at least one blade (24) being fixed on the hollow cap. Device according to any one of claims 1 to 31, characterized in that the lower radial edges (27) blades (24) are extended by elements of blades (37) articulated in rotation around said edges radials (27) between a first position at rest where the blade elements (37) are substantially perpendicular the blades (24) when the turbine is not active, and a second active position where each blade element (37) is substantially in the same plane as the blade (24) associated when the turbine is in action. Device according to claim 32, characterized in that that the blade elements are forced into the position of rest by an elastic element (38), the passage of the rest position at the active position being due to the forces of inertia and centrifugal induced by the printed rotation by the turbine with the blades (24) and the blade elements (37). Device according to any one of claims 1 to 33, characterized in that it has two large blades (24) intersecting on the axis (100) so as to create four half-blades, and in that the two blades (24) intersecting right angle, each half-blade includes a blade element (37) in a quarter circle, so that in position rest, the blade elements (37) form in combination a cover closing the lower base (28) of the cavity (25).

Images