ES2289070T3 - VENTILATION DEVICE WITH SPIRAL AIR CHANNELING. - Google Patents

Abstract

Ventilation device with spiral air ducting that facilitates the extraction of air in a spiral, either in a mixed way, dynamically with a motorized fan blade or by physical convection of a thermal origin, with the air forced to leave the device tangentially fan, in which the device is provided, for this purpose, with a base (3) and a baffle (2), both spherical, without holes or cuts, made of galvanized sheet or stainless steel, and is also provided with a chimney defined by a cylindrical body (1) inside which the motorized fan (7) and the motorized window (5) responsible for the opening and closing of the passage of air in the chimney, in which at the lower end are housed of the cylindrical body (1) there is a part or flap (10) to cover part of the spherical base (3) in which: - the spherical base (3) is articulated according to the inclination of the ceiling, for which it is provided with a flat peripheral flap (3.1) that allows fixing said base to the ceiling, and - in the spherical shaped part of the base (3), an endless circular cut is provided so that it should not be shortened for each inclination of the roof. - the spherical deflector (2) is supported by the supports (6) in the form of "Z" or similar that help the formation of the air spiral and its tangential escape; These supports (6) are connected to the spherical baffle by welding and are regularly distributed with an outlet angle greater than 90 °, thus allowing the spiral formation of air to end tangentially.

Description

Ventilation device with ducting spiral air

Object of the invention

The present invention relates to a ventilation device with spiral air ducting, of between industrial ventilation devices, preferably mounted on a roof

The present invention is characterized, between other factors, by allowing a spiral air extraction that facilitates extraction in a mixed way, performed well dynamically with a blade driven by a motorized fan or by natural physical convection using thermal gradients of air.

The objects of the invention are also physical and structural characteristics of the device ventilation, which in combination and when mounted together facilitate the extraction of air in a spiral, providing also greater structural rigidity to resist the forces of wind, resulting in improved behavior in general and in a considerable noise reduction, reducing vibrations transmitted.

In this way, the present invention belongs to the field of air extraction equipment or fans.

Background of the invention

The ventilation devices available in the actuality in the market carry out the extraction well through Venturi systems or through mixed systems, through Convection with specific designs. In all solutions previous ventilation devices are made from of cut, folded and perforated sheets, joined by rivets tubular or surface screws in the upper cone or in the base.

In other cases, ventilation devices they are made from a single piece with resins of polyester, although this presents certain disadvantages since diameters greater than 500 mm are difficult to obtain due to the structural problems encountered when affected by the outside temperatures to which they can be subjected.

In addition, in order to avoid rain, the convection or motorized devices have cones with large diameters in relation to the chimney body, which hinders a correct suction in the case of convection.

It is also noted that the devices of wrapping ventilation considerably reduces the performance, since they force the flow to rotate 180º.

In relation to ventilation systems based on Venturi, these suffer from a serious disadvantage, such as pressure loss through its lateral openings, since these are used with an engine, while those devices that do not use an engine only reach an efficiency of 30% of flow.

An additional difficulty found in the ventilation devices available today is the way of union to the ceiling, since this one is made to measure, depending on the inclination of said roof, where the base used for joining the floor comprises various parts welded and riveted together. This Solution does not ensure tightness.

Also frequent is the case in which means currently used to ensure the engine consist of metal sheets joined as tie rods, whose Total surface offers resistance to the passage of air, and where place the junction box on one side, increasing additionally air resistance. Finally, I should mention that devices such as those installed in the currently they have the electrical installation outside the device, exposed to environmental hazards.

In the state of the art there are some known ventilation devices, such as those disclosed in EP patents 802.378 A, US 2001/039776 A and GB 865730 A. In the EP 802.378 patent is disclosed, in particular, a baffle spherical which is provided with a cylindrical body whose end Bottom is provided with a spherical base. In the US patent 2001/039776 a roof ventilation duct is disclosed with a piece fixed to the structure, in which galvanized metal is used to prevent oxidation, and GB 865730 is disclosed an upward discharge fan provided with an engine. Without However, none of these ventilation objects is provided with means to be attached to a spherical base in the ceiling, and with means that avoid carrying out an additional correction in the base depending on the slope of the roof, and in which the extraction of air or air in a spiral is facilitated by position and special shape of the spherical deflector supports.

In this way, the object of the present invention is to overcome the disadvantages indicated above of the ventilation devices, providing one that allows a Improved adaptation and joining of the device structure ceiling ventilation, prevents the entry of rainwater, has a structure that is not made from cut sheets, folded and perforated joined by rivets, has no loss of pressure at all and in which the entire unit is designed in a way that offers minimal air resistance and favors a spiral air duct.

Description of the invention

The invention disclosed of a device for ventilation with spiral air ducting comprises a device that performs a spiral air extraction in a way gradual, sucking air from the inside through a way spherical, in which the opening window and closure, engine support fins, fan blades motorized, the spherical deflector and its supports. With all this I know achieves a hurricane effect for air movement that reduces load losses due to residual turbulence and improves flow rates, since at all times the air operates with spherical, cylindrical or conical wrap surfaces.

The ventilation device subject to invention basically comprises an articulated spherical base, a spherical baffle, its tangential supports and a cylinder that is The body of the chimney.

Both the articulated spherical base and the spherical baffle are curved surfaces and in this way provide the whole with greater structural rigidity that allows resist the force of the wind in any direction, since it Minimizes wind resistance. Both are made with a Galvanized metal sheet or stainless steel and in one piece, no holes, cuts or joints so that moisture or rain they will not affect in any way and torsions, wear and tear are prevented. oxidation.

The spherical base is articulated so that It can adapt to the inclination of the floor. It has the shape of a spherical lid and joins the chimney body, a cylinder, in any point. The insertion between the two is circular and in the case of sloping roofs, part of the surface of the spherical base It may be discovered. In order to cover this part of the base spherical a flap is provided at the base of the chimney to cover or separate be placed on the exposed hole, so that Do not enter rain at the articulated spherical base. It also turns out possible to make a hole at the exact point of union of the two parts and then weld them together.

The cylindrical body or chimney is where the air is conducted, either directly from inside the enclosure from which it must be removed or through a tube telescopic and flexible.

Inside the cylinder the box is installed of fan and window cover connections, designed for spiral air ducting.

The motorized window is responsible for opening and Close the air passage. It has a circular shape crossed by a axis that rotates it 90º when opening or closing. The window has a wave-like way to help air formation spiral when air passes through it. This form of window provides greater rigidity and increases its inertia in the direction of rotation of the cover.

The motorized fan is fixed to the body cylindrical by a number of support points in the form of fins with form of "Z" or "U" that are perpendicular to the engine and that are rotated a certain angle of the center of the engine, forcing This way to air to spin in a spiral. The design of these supports is such that the system has virtually no inertia in the motor torsion direction, allowing the engine to absorb torsional vibrations through its own movement and also preventing pressure losses since these fixations are positioned perpendicular to the rest of the cylindrical body.

In addition, in order to favor the passage of air through the inside of the cylindrical body the junction box of the motorized fan, instead of being placed next to said fan, is placed under it. Electrical installation it is also arranged so that it always extends inside of the cylinder, without exposed wires in order to prevent its wear due to environmental conditions or accidents.

In addition, the upper neck of the chimney is provided with two circular flanges parallel to the height of the blade, in order to obtain greater efficiency during extraction and drive while minimizing cylinder ovalization as well as a constant flow rate is provided by the blade suction opening adjustment.

In relation to the deflector supports spherical, these are crucial to redirect the air to a spiral and are made from a folded sheet in the form of "Z" or in a similar way. The number of fixations provided It will depend on the size of the device, the wind pressure to withstand and higher order harmonics of the fan. With the In order to prevent holes in the baffle, the fixings are welded to said deflector to form a single piece. Be screwed to the cylindrical neck, for cleaning and maintenance, in a point protected from the rain.

The spherical deflector is made from a matrix or mold from a single piece of sheet metal galvanized or stainless steel. Because it has form spherical, it has a greater structural rigidity and because it does not It has cuts or joints is not affected by moisture and factors environmental. Its shape provides reduced resistance to outside air while helping natural convection and preventing unwanted turbulence for indoor air extraction, while helping to distribute the air extracted in parts same. In addition, because its radius is progressive, the trajectory of the air ends tangentially. This baffle does not require use of a return flow prevention element, avoiding this way load losses and reducing vibrations.

As an option, it is possible to install an element of return flow prevention or an inner cone with materials absorbents to compensate the shadow of the blade core.

Description of the figures

In addition to the description provided later and in order to facilitate a better understanding of the characteristics of the invention the present specification is accompanies a set of drawings with figures in which, by way of of illustration and in a non-limiting sense, the most relevant details of the invention.

Figure 1 shows a sectional view of the length of the total length of the mounted unit.

Figure 2 shows a plan view of the unity.

Figure 3 shows a representation of the fan unit with vertical window.

Figure 4 shows the same as Figure 3, with the window placed horizontally.

Figure 5 shows the window in a view in perspective.

Figure 6 shows an example of a form of realization for engine mounts.

Figure 7 shows another example of a form of realization for engine mounts.

Figure 8 shows the arrangement of the Engine mounts between the cylinder and the engine itself.

Figures 9, 10 and 11 show several examples of embodiments for the flow prevention element of return.

Figure 12 shows the joint between the cylinder and the articulated spherical base.

Figure 13 shows the same as figure anterior in the case of a slightly sloping roof.

Figure 14 shows the connection form of the engine.

Figure 15 shows the flaps at the end upper cylinder.

Figure 16 shows the shape of the supports for the spherical baffle.

Figure 17 shows the effect of the supports of the spherical deflector with the air and wind escape.

Embodiment of the invention

In relation to the figures it is provided to below a description of a preferred embodiment of the invention, as well as a description of the figures.

Figure 1 shows the device ventilation, basically composed of a cylindrical body (1) or fan neck, a spherical deflector (2) located in the part upper and an articulated spherical base (3) in which the complete set and that is used for fixing to the ceiling. Too the supports (6) to which the deflector is welded are shown spherical (2). The cylindrical body (1) is the chimney in which the device conducts the flow, which can be directly connected inside the enclosure or connected by a telescopic duct flexible (4), as shown in the figure.

Inside the cylindrical body (1) there is a motorized fan (7) with its corresponding blades and the motorized window responsible for opening and closing the fan.

Figure 2 generally shows the same parts described above, and shows the fan supports (8) motorized (7) to the cylindrical body (1) and the air exhaust tangential with the help of the supports (6) of the spherical deflector (2). Next and in successive figures the details will be shown constructive of the set in greater detail.

Figures 3, 4 and 5 show the most important characteristics of the motorized window (5), intended to open and close the air flow. Basically the window (5) is shaped as a circle with an axis along one of its diameters Figure 4 shows the profile of the window (5) that it's basically shaped like a wave so when it's Vertical helps the formation of a spiral in the air. This form provides advantages by reinforcing the cover without the need for reinforcements that must be welded to it, increasing inertia in the direction of rotation of the cover.

Figures 6 and 7 show two possible ways for the supports (8) of the motorized fan (7) to the cylindrical body (1). As shown in Figure 6 these they are Z-shaped, while those shown in Figure 7 are U-shape. In any case, its ends have folds that define trapezoidal ends (8.1), (8.2), (8.3) and (8.4). Sayings supports (8) are placed rotated with respect to the center, forcing the air to move in a spiral towards the fan blade (9), providing increased performance and less noise.

Figure 8 shows in broken line the voltages applied to the supports (8); said support system (8) reinforces the structure of the unit by improving the distribution of the load, and also has a practically zero inertia in the motor torsion direction, allowing torsion movement of the support that favors the absorption by the engine of its own torsion vibrations in its movement. Because the system supports absorbs vibrations, prevents them from being transmitted to the unity. In addition, and because it is placed perpendicular to the body cylindrical (1), prevents pressure losses.

Figures 9 to 11 show various types of baffles, all in the form of a spherical cap in one piece, made of galvanized sheet or stainless steel. Said deflector (2) has a minimized air resistance due to to the shape of its surface, it helps natural convection and Prevents unwanted turbulence.

Figure 10 shows the baffle (2) with a return flow prevention element (2.1) while the Figure 11 shows the return flow prevention element (2.2) in the form of a drop of water. These prevention elements of return flow are intended to compensate the core shadow of the chosen blade.

Figures 12 and 13 show the union of the body cylindrical (1) and spherical base (3). Said spherical base has a flat area (3.1) for ceiling attachment and a central bulge in the form of a spherical cap, in which a hole is provided. For this hole to be valid regardless of the roof inclination, an endless circular cut is made from the center of the lid with the largest possible diameter. Because the junction between the cylindrical body (1) and the spherical base (3) leaves a uncovered part (11) (as shown in Figure 13), in the bottom of the cylindrical body (1) a sheet or part (10) is welded covering said sphere on the required surface.

Figure 14 shows the layout of the box (12) of the motorized fan (7), installed under the engine with the In order to reduce air resistance. In addition, the installation electric (13) always extends inside the body cylindrical (1), preventing wear due to contact with the ambient.

Figure 15 shows, on the upper edge of the cylindrical body (1), two circular flanges parallel (15) to the blade height (9), which provide improved efficiency in the extraction and drive while minimizing ovalization of cylinder and improve its performance by adjusting the window to the blade and reducing the noise.

Finally, Figure 16 shows the supports (6) of the spherical deflector (2). These supports (6) are made from a folded sheet and are "Z" shaped or similar, and are attached to the baffle (2) by welding.

Figure 17 shows the air leak in a spiral inside the cylindrical body (1), which ends tangentially with the help of the supports (6) of the deflector spherical (2) and air.

It should be noted that the brackets are regularly distributed and have a higher exit angle at 90º, allowing the spiral to end tangentially and protected from wind pressure.

The terms used herein They should be understood in a broad and non-limiting sense.

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References cited in the description

This list of references cited by the Applicant is provided for the convenience of the reader only. This list is not part of the European patent document. Despite that great care has been taken during the collection of references, the possibility that they have been errors or omissions occurred and in this regard the EPO exempts itself from all responsibility

Patent documents cited in the description

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EP 802378 A [0012] [0012]

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US 2001039776 A [0012] [0012]

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GB 865730 A [0012] [0012]

Claims (9)

1. Ventilation device with ducting of spiral air that facilitates the extraction of air in a spiral, well in a mixed way, dynamically with a fan blade motorized or by physical convection of a thermal origin, with the air forced to leave the device tangentially fan, in which the device is provided, for this purpose, with a base (3) and a baffle (2), both spherical, without holes or cuts, made of galvanized sheet or stainless steel, and is also provided with a chimney defined by a cylindrical body (1) inside of which the motorized fan is housed (7) and the motorized window (5) responsible for the opening and closing of the passage of air in the chimney, in which at the lower end of the cylindrical body (1) there is a part or flap (10) to cover part of the spherical base (3) in which: - the spherical base (3) is articulated according to the roof slope, for which it is provided with a flap flat peripheral (3.1) that allows fixing said base to the roof, and - on the spherical shaped part of the base (3), an endless circular cut is provided so that no It must be shortened for each roof slope. - the spherical deflector (2) is supported by the brackets (6) that have a "Z" shape or similar that help the formation of the air spiral and its tangential escape; these supports (6) are attached to the spherical deflector by welding and They are distributed regularly with an exit angle greater than 90º, allowing the spiral air formation to end tangentially 2. Ventilation device with spiral air duct according to claim 1, characterized in that the motorized window (5) has a circular shape crossed by a diametral axis, and a wave-shaped profile. 3. Ventilation device with spiral air duct according to claim 1 characterized in that the fixing of the motorized fan (7) to the cylindrical body (1) is carried out by means of Z-shaped supports (8) with their ends folded to define trapezoidal surfaces ( 8.1) and (8.2). 4. Ventilation device with spiral air duct according to claim 1 characterized in that the fixing of the motorized fan (7) to the cylindrical body (1) is carried out by means of U-shaped supports (8) with their ends folded to define trapezoidal surfaces ( 8.3) and (8.4). 5. Ventilation device with spiral air duct according to claim 1 characterized in that the motorized fan (7) has a connection box (12) installed therein. 6. Ventilation device with spiral air duct according to claim 1 characterized in that the electrical installation (13) that reaches the connection box (12) of the motorized fan (7) extends inside the device. 7. Ventilation device with spiral air duct according to claim 1 characterized in that the upper part of the cylindrical body (1) is provided with two parallel circular flanges (14) at the height of the blade (9). A ventilation device with spiral air duct according to claim 1, characterized in that the spherical deflector (2) is provided with a return flow prevention element (2.1) to compensate the shadow of the core of the chosen blade. 9. Ventilation device with spiral air duct according to claim 1 characterized in that the spherical deflector (2) is provided with a return flow prevention element (2.2) to compensate the shadow of the core of the chosen blade.