BR102016012924A2 - SYSTEM FOR AIR CIRCULATION IN A CLOSED ENVIRONMENT - Google Patents

Abstract

The present invention relates to a system for circulating air in a closed environment, operating contrary to the natural thermal convection phenomenon. In general, it is an "air fountain". which captures air from the installation base (ground), redirecting it to the top and allowing 360 ° ventilation. The system releases an air mass at a temperature lower than that of the air mass on the pressure face due to the difference in height between the suction and pressure faces. thus, the user's feeling when using the system would be not only of a freshness due to the air movement itself, resulting from the ventilation phenomenon, but also to the colder air layer that is dispersed at the top of the enclosure in which it is used. is found.

Description

AIR CIRCULATION SYSTEM IN A CLOSED ENVIRONMENT

FIELD OF INVENTION

[001] The present invention falls within the field of application of engineering, specifically mechanics, as it relates to a system for circulating air in an enclosed counter convection environment. In general, it is an "air fountain" that captures air from the installation base (ground), redirecting it to the top and allowing a 360 ° ventilation, giving the user a feeling of freshness.

BACKGROUND OF THE INVENTION

Fans are motor flow machines that transfer energy to the fluid through the action of a rotor. Ventilation systems have the function of conducting fluids (which can be both gases and liquids) between two environments, reservoirs, equipment, devices, etc.

Of course, the nature of each working fluid (ie the one in contact with the flow machine), as well as the functions of the machines, make some processes and phenomena specific to gas movement, and others, the movement of liquids.

[004] For example, there are fans that do not require the use of a pre-ventilation system: they are those used in the movement of ambient air (column, ceiling fans, etc.). Others do it more efficiently when connected to suction and / or discharge pipes.

Thus, the basic function of a fan is therefore to provide the energy necessary to move a given amount of air through a ventilation system connected to it.

[006] Fans can be divided into basically two large groups: axial fans and centrifugal fans. In the first one, the flow of the working fluid is mainly axial, ie parallel to the axis of rotation. Centrifugal fans, in turn, are those where the main fluid flow is radial.

Usually, home fans are axial type because they are cheaper and have less noise and moderate efficiency, while centrifugal fans are used in industrial installations because they move more air even though they are more expensive and less expensive. generally present higher noise.

Ventilation systems are known to provide freshness, however, existing systems often do not meet the needs and / or expectations of users, as the proximity between the suction and discharge faces of the system may not be large enough to ensure adequate ventilation of the environment.

Accordingly, the present invention refers to a system for circulating air in a closed environment, wherein a soil air mass is captured and channeled through a pipe, making use of the counter convection phenomenon.

TECHNICAL STATE

The documents BR 202013000037-5 U2, US8167542 Bl and WO2015074166 Al disclose ventilation mechanisms that direct the air flow 360 ° concomitantly, that is, at all times there is air exiting radially from the plane that cuts the mechanism crosswise. However, the devices act as usual fans when the inlet air mass they work with is close to the outlet air mass, that is, the intake and discharge air faces are very close and there is no effect. of counter convection explored in the present invention.

[0011] Documents PI0507080-5 A and PI0518716-8 A2 consist of mechanisms that use the centrifugal fan concept for operation, the first being a centrifugal fan and the second a centrifugal fan used in particular for automotive applications, Mounted with a housing for tubular air flow direction at the outlet of the mechanism. Both mechanisms use centrifugal fans for operation, but have a different use and process of ventilation than that of the system of the present invention, which uses a centrifugal fan to capture a mass of air from the ground and to channel it. it through a tube.

PI0815785-5 A2 consists of a bladeless ventilation system, with the outlet air flow coming from the peripheral part of a circular nozzle. The mechanism resembles that addressed in the present invention as regards the distinction between the suction and discharge faces of the proposed ventilation system. The disparity, however, lies in the absence of the counter convection phenomenon approach aiming to favor the temperature gradient that the vertical distance between the faces provides, besides the ventilation direction itself, which can occur in 360 ° for both sides. mechanisms, but not concomitantly to the said system, since the flow generated by it is unidirectional, with this direction adjusted by the rotation of the mechanism.

WO2007042894 Al consists of a mechanism that causes forced air circulation within it by suction of air at its bottom, providing convective heat exchange between circulating air and a fluid in a radiator, and heat or cool the air depending on the temperature of the liquid in the radiator. The mechanism releases air whose temperature has changed at its top. In the system of the present invention there is no use of radiator, but only of ambient air, without changing its temperature by the use of other fluids, providing temperature circulation and homogenization, exploiting the natural convection on the outside of the mechanism. Although this document reveals a ventilation mechanism that has some similarities with the present invention, mainly by using air circulation by pulling it close to the ground and releasing it about 70 cm above, but there are important distinctions: 1) the mechanism alters the temperature of the air passing through it through a radiator that can both heat and cool the air; 2) the height at which air is released is much closer than in the case of the present invention, not constituting a significant natural temperature gradient and 3) the resulting air flow is unidirectional. The convection in which this mechanism is concerned is fluid with a temperature change to air rather than the environment itself.

In summary, although the concept of convection heat exchange is used in several of the inventions cited, it differs from that proposed in the present invention in that the exchange occurs either between fluid and gas, or in the natural sense of convection within the mechanisms. . In the present invention, forced counter convection inside the mechanism (without heat exchange) is used for later release at the top of the room, at an angle of 360 °, providing heat exchange by natural convection on the outside of the mechanism.

Thus, the present invention proposes a system for circulating air in an enclosed environment, which uses a centrifugal fan to capture a mass of air from the ground and channel it through a pipe using the counter convection phenomenon.

BRIEF DESCRIPTION OF THE INVENTION

[0016] The present invention relates to a system for circulating air in a closed convection environment which utilizes a centrifugal fan, a tube and an air dispersing funnel for its operation. Generally speaking, it is a system that aims to capture the air mass from the base of a certain environment or enclosure (colder), taking it to the top of it and expelling it in a region whose air layer has the highest temperature. due to the difference in heights. The system therefore operates contrary to natural convection, whose natural phenomenon would cause the lower temperature air mass to descend to the base of the enclosure and the higher temperature to rise to the top of the enclosure.

BRIEF DESCRIPTION OF THE FIGURES

[0017] Figure 1 shows the proposed ventilation system schematically.

[0018] Figure 2 shows the proposed ventilation system in perspective.

Figure 3 shows the proposed ventilation system in a front view.

Figure 4 shows the proposed ventilation system in front and side views.

DETAILED DESCRIPTION OF THE INVENTION

[0021] The present invention relates to a system for circulating air in a closed environment which operates in a manner contrary to the natural thermal convection phenomenon, preferably comprising a centrifugal fan at the base of the system (3), a tube Upright to the fan (2), an air disperser connected to the pipe (1) and complementary accessories (not shown in the figures) made of materials such as aluminum, PVC or other non-flexible rigid plastics.

[0022] The system works contrary to the natural thermal convection phenomenon, that is, by capturing the air mass from the base of the system (soil) at a lower temperature and throwing it to the top where the air is a higher temperature, contrary to natural thermal convection. Consequently, the air rejected by the system at a temperature lower than the local air mass will tend to fall, this time observing natural thermal convection.

[0023] The system comprises a centrifugal fan for capturing air from the base of the enclosure and redirecting this air mass to the pipe (2) connected to it. However, it is noteworthy that the mechanism is not limited to a centrifugal fan to operate, which was selected to favor the flow of air to the tube; If an axial fan was chosen, a nozzle would need to be used for the air taper between the fan and the pipe.

The system comprises a vertical pipe connected to the fan (3) whose diameter is such as to allow air flow with minimal loss, reduced noise, and support the disperser (1) at its top, and whose height can be adjusted. , from telescopic joints or by making a concertina section, similar to a "straw".

The diameter and height of the vertical pipe (2) depend on a combination of factors such as the pipe material, the wall thickness of the pipe and the ceiling height of the enclosed environment, for example, as well as the presence of possible additional accessories as provided herein.

Adjusting the height of the tube (2) will directly influence the flow intensity and the temperature gradient of the air rejected by the mechanism, as well as the noise generated during operation.

[0027] The system comprises an air spreader, the wingspan of which can be adjusted, and the direction of the outgoing air flow can be chosen, that is, the flow back to the floor or ceiling.

The system comprises complementary fittings, such as an air humidifier, whose nozzle would be inserted into the tube (2), causing the air flow to carry particles of vaporized water as it flows; an odorizer from a mechanism similar to the humidifier but with flavored liquid; and a particle protection and retention filter on the suction face of the fan, as well as a casing on the base fan (either centrifugal or axial) to attenuate the noise generated by the equipment.

In addition, the system is not limited to a specific building material for the manufacture of the aforementioned components, which may be made of materials such as aluminum, PVC or other rigid and non-flexible plastics to reduce the overall weight of the mechanism while maintaining due rigidity necessary to the system operation.

[0030] In Figure 1, the schematically proposed system is illustrated, illustrating how cold air from the base of the enclosure forcibly travels through the fan motor and is released at the top of the enclosure, acting contrary to natural convection. .

In Figure 1, the arrows indicate the air flow and location. The wavy arrows (Q) show the location of the warmer air remaining in the upper region (hatched) by natural convection and the lighter arrows (F) represent the cooler air inside and outside the proposed system and show the change in the proposed flow, forcing cold air to rise through the interior of the system, contrary to natural convection.

Convection in fluids occurs as a function of density difference: warmer gases (or liquids) expand and consequently reduce density, while colder ones contract, resulting in increased density, and as a result , the colder gases remain closer to the ground by gravitational attraction, occupying the volume of the warmer gases that thus remain in the higher regions.

In the proposed system, the cooler air (F) near the ground is captured at the bottom of the system (3), consisting of a suction nozzle and a flow direction mechanism, channeled into the intermediate sector of the system ( 2) a low-turbulent duct whose height A varies with the environment to be affected, so as to raise the cold air to the warmer air concentration region and, finally, the cold air is released at the top of the system (1), being distributed to interfere with the hot air region (Q). The interference generates a region of greater relative comfort in the generic area delimited with a dotted circle (or the cone under the hatched region), which represents the place of human permanence, aiming to improve the thermal comfort conditions through the cross circulation of the air stream. cold (F) affecting the hot air region (Q).

The system, operating at steady state, tends to even out the temperature, and, depending on ambient conditions, produces a feeling of comfort reported in testing as more favorable than in the case of unidirectional or multi-directional fans that do not operate with temperature gradients.

[0035] The technical solution for the system is illustrated in the other figures, by way of example, there may be variations depending on the application and aiming to optimize the performance of the proposed system.

[0036] In Figure 1, the bottom of the system (3) should maximize the capture of colder air by observing unwanted particle filtration (dust, debris and smoke, for example), minimizing flow losses in the redirection to the duct. (part 2 of the system), generate minimal heating of the captured air (either by friction, compression or proximity to electric motor) and not cause significant noise that compromises comfort conditions. In part 2 of the system, the duct shall be of lightweight material such as aluminum, PVC or other rigid and non-flexible plastics, with minimum roughness, with reduced pressure drop and low turbulence or noise generation. The height A of the duct (2) should be such that it conducts the cooler air from the lower region of the environment (floor) to the region about one meter above the place of human permanence (eg 2.5 meters in a place with a ceiling height of 2.7 meters). Finally, the flow distributor (1) must cause minimal loss and must be adjustable so as to be able to direct flow according to the occupancy conditions of the environment.

Figures 2 to 4 presented are intended to illustrate the proposed system. Figure 2 presents the approached system in perspective. Figure 3 presents the front view of the system as well as the arrows indicating the direction of air flow (F) flowing through the system, while (Q) represents the air mass outside the system. Figure 4 finally presents the front and side views of the system.

The present invention will now be described with reference to the drawings without, however, wishing to limit the invention to what is disclosed in the drawings.

In Figure 2, a perspective of the proposed system is illustrated. In this figure, the part that promotes air distribution (1) is molded from plastic and fits into the duct (tube) (2) of varying height. Note that the duct (2) is represented with a section. The duct (2) fits into the air outlet nozzle of the centrifugal fan (3), whose hull as well as that of the fan motor (4) is molded from plastic. The motor rests on a base (5), also molded in plastic and containing 4 rubber feet whose function is to reduce the transmission of vibration and prevent the movement of the mechanism.

In the sectional diagram shown in Figure 3 the lighter gray arrows (F) show the cooler air flow, which is drawn by the centrifugal fan rotor closest to the floor of the system where it is installed. This air is then driven through the centrifugal fan, directed to the variable height duct and finally released into the upper part of the system. The darker gray arrows (Q) represent the natural flow of warm air by the convection principle.

[0041] Figure 4 shows two views of the system, one front and one side. In this figure it is possible to identify, as in Figure 2, and with the same numbering, the part that promotes air distribution (1), consisting of an upper cover (9) that directs the air flow down and sideways evenly, a locking base (10) and upper cover holding fins (11). This piece (1) fits into the duct (2) of variable height (A), with a minimum height of 2 meters and a maximum of 3.5 meters without intermediate supports or up to 7 meters with intermediate clamps. The duct (2) fits into the air outlet of the centrifugal fan (3), which has a propeller (8) coupled to the shaft of a motor (4) isolated by a housing. The whole system rests on a base (5) that surrounds the motor shell (4) and has ventilation slots (7) to disperse the heat generated by the fan motor. The electric motor is powered by a power cable (6) plugged into an outlet.

Although the invention has been widely described, it is obvious to those skilled in the art that various changes and modifications may be made without such changes being covered by the scope of the invention.

Claims (6)

1. Indoor air circulation system, characterized by drawing the cooler air from the base of the room in which it is located and releasing it into the highest part of the room, preferably comprising a centrifugal fan at the base of the system ( 3) a vertical pipe connected to the fan (2), an air disperser (1) connected to the pipe and complementary accessories. System according to claim 1, characterized in that it preferably comprises a centrifugal fan (3) for capturing air from the base of the enclosure and redirecting this air mass to the tube (2) connected thereto and optionally a axial fan with a nozzle for the air taper between the fan and the pipe. System according to claim 1, characterized in that it comprises a vertical tube (2) connected to the fan (3) of adjustable diameter and height from telescopic joints or a folding section. A system according to claim 1, characterized in that it comprises an air disperser (1) connected to the adjustable span tube (2) to choose the direction of the outgoing air flow. System according to claim 1, characterized in that it comprises complementary accessories, preferably an air humidifier, an odorizer, a particle protection and retention filter on the suction face of the fan and a housing on the base fan. System according to any one of Claims 1 to 5, characterized in that it is preferably made of a constructive material to reduce the overall weight of the system and to maintain the rigidity required for the system to function, such as aluminum, PVC and other rigid and non-flexible plastics.