FR3101937A1 - Building ventilation device - Google Patents

Abstract

Building ventilation device 1, comprising an air inlet duct 3 for receiving air downstream of a fan 2, a distribution plenum 4 disposed downstream of the air inlet duct 3 and provided with a plurality of air outlets, each air outlet comprising a cylindrical skirt, a plurality of air distribution ducts 5, each fluidly connected to one of the outlets, each air distribution duct 5 comprising a perforated duct area, at least one pressure sensor 7 disposed in one of the air outlets and fixed to the skirt of said air outlet, at least one controlled shutter register (8) disposed in each air outlet equipped with said at least one pressure sensor 7, the shutter register (8) being mounted upstream of the corresponding pressure sensor 7, and a control unit configured to receive pressure information from the at least one pressure sensor 7 and to send an instruction to the at least one shutter register (8). Figure for the abstract: Fig. 1

Description

Building ventilation device

The invention relates to the ventilation of premises with human or animal presence. In such premises, the air is renewed frequently to ensure quality ambient air. The human or animal presence can be permanent, temporary, occasional or repeated.

Some applications provide for heating by the ventilation air. For reasons of comfort and safety, the temperature difference between the ambient air and the incoming air which is warmer than the ambient air is a significant parameter. In an application with ventilation air cooling, the temperature difference between the ambient air and the supply air which is colder than the ambient air is a significant parameter. Condensation phenomena can also occur.

From another point of view, a low temperature difference between the ambient air and the incoming air is desired by the users called upon to be present or to enter the room concerned. However, a small temperature difference between the ambient air and the incoming air requires high airflows. The flow velocity is limited to avoid turbulence that is harmful to the flow and generates significant energy losses. Furthermore, the diameter of the sheath is limited by the constraints of space within the building, of the mass to be supported by the structure of the building, of the mass of each part to be handled and assembled, of the transport gauge and of the manufacturing.

A difficulty with ventilation systems is the complexity of the airflows. There is sometimes a difference between the flow modeled on a computer in the design office and the actual flow measured. It has been proposed to add a manually adjustable leak to a sheath, see EP 2 224 183. This amounts to correcting a design, manufacturing or installation fault by static means. However, the effect of the fault is likely to vary depending on factors such as the ambient temperature, the temperature of the injected air, the atmospheric pressure, the air flow, etc. In addition, the Applicant noticed during modeling of such installations that the effect of the leak was also variable depending on several factors. In short, the defect is much more complex to correct. Indeed, the ventilation system is supposed to provide an air flow with a speed at head height at any point in the room within a determined range, the lower limit of which guarantees sufficient renewal and the upper limit guarantees the comfort of the occupants. people or animals. A particularity of air flows is their non-linearity. Thus an increase in the flow rate of a ventilation system can result in a stagnation of the air speed at a first point of the room at human height, a decrease in the air speed at a second point room at head height, and an increase in air speed at a third point of the room at head height. A static correction is therefore outdated today.

A method for regulating an air flow in an air conditioning installation has also been proposed according to EP 2 557 368. A pressure or flow detector is arranged in a zone located between a conditioning unit of air and a flow interruption element. However, this process, analyzed by the Applicant, does not make it possible either to remedy the above defects, or to homogenize the air in the room, or to effectively reduce the differences in air temperature between the ground and the top of the room. , neither to guarantee optimum operation at start-up and in steady state, nor to reduce regulation errors.

The Applicant considers that the remediation of some of these drawbacks depends on the quality of the modeling of the premises and the ventilation system, the manufacture and installation of the ventilation system. While other of these disadvantages require a ventilation system to correct, avoid or overcome them structurally.

Continuing its research, the Applicant discovered that the positioning of the flow interruption elements and the positioning of the pressure or flow detector were defective and did not allow proper regulation.

There is a need to provide, at any point of a building within a range of heights used by people or animals, a heating/cooling power, surface or volume, determined with a controlled temperature difference and an ambient air speed. in the building under control, with dynamic adjustments of temperature, flow and interruption of this or that diffusion duct.

The invention satisfies such requirements which are at least partly contradictory.

The Applicant has developed a building ventilation device with great flexibility of use, allowing a homogeneous distribution of the air in the zones of the building, a rapid mixing of cold air and hot air in the event of stratification thermal, comfort of use of the building and adaptation to different uses of the areas of the building.

The invention proposes a building ventilation device, comprising an air inlet duct for receiving air downstream from a fan, a distribution plenum arranged downstream of the air inlet duct and provided with a plurality of air outlets, each air outlet comprising a cylindrical skirt, a plurality of air diffusion ducts, each fluidly connected to one of the outlets, each air diffusion duct comprising a perforated duct, at least one pressure sensor arranged in one of the air outlets and fixed to the skirt of said air outlet, at least one controlled shutter damper arranged in each air outlet equipped with said at least one sensor pressure, the shutter damper being mounted upstream of the corresponding pressure sensor, and a control unit configured to receive pressure information from the at least one pressure sensor and to send an instruction to the at least one damper shutter.

In one embodiment, the building ventilation device comprises a plurality of pressure sensors each disposed in one of the air outlets and attached to the skirt of the corresponding air outlet. Each air outlet can be equipped with a pressure sensor. Alternatively, each air outlet except one can be provided with a pressure sensor.

In one embodiment, the distribution plenum has a rectangular parallelepipedal shape, with at least one side connected to the air duct to receive air downstream of the fan, at least one side provided with at least one outlet air, and at least one solid side, the plenum having walls each forming one of the sides outside the air outlets or air inlet, said walls comprising several layers.

In one embodiment, the distribution plenum is made of sheet metal lined with insulating material. The distribution plenum can comprise two sheets and an inorganic or organic insulator, arranged in a sealed manner between said sheets.

In one embodiment, the building ventilation device comprises said fan downstream of which the air inlet duct is arranged.

In one embodiment, the building ventilation device comprises a plurality of distribution plenums arranged downstream of the air inlet duct, a first distribution plenum being connected to the air inlet duct and supplying the other distribution plenums. The first distribution plenum or master plenum supplies the others or subordinate plenums. Subordinate plenums can be rank 1 supplied by the master plenum, rank 2 supplied by a subordinate rank 1 plenum, etc.

In one embodiment, the building ventilation device comprises a plurality of distribution plenums each arranged downstream of an air inlet duct, downstream of the fan. The fan supplies several air inlet ducts, each of which can supply at least one distribution plenum.

Other characteristics and advantages of the invention will become apparent on reading the following detailed description, with reference to the appended figures, which illustrate:

Figure 1: a schematic view of the device according to one aspect of the invention;

Figure 2: a perspective view of a plenum of the device according to one aspect of the invention;

Figure 3: a sectional view of the plenum of Figure 2;

Figure 4: a top view of the plenum of Figure 2;

Figure 5: a front view of the plenum of Figure 2;

Figure 6: a perspective view of a plenum of a device according to another aspect of the invention.

In general, a building to be ventilated comprises a floor, walls or closed partitions and an upper surface formed by a ceiling, an underside of a roof, etc. Partitions and floors can delimit an interior space of the building into zones. In terms of aeraulics, each zone is described by a certain number of characteristics: height, width, length, openings, obstruction by furniture or machinery, duration of occupation - permanent, temporary, intermittent or exceptional - type of occupancy – human or animal, standing or sitting, etc., air leaks, insulation, sun exposure. The needs of each zone in terms of air renewal, heating and/or cooling are thus estimated by calculation. However, predicting the precise operating conditions of a ventilation installation is difficult. The quality of the components and installation of the installation greatly contributes to this.

The need is to provide energy-saving ventilation while offering high comfort to the users of the building, which implies avoiding excessively high local air movement speeds that generate feelings of drafts, or even inconveniences. physical or medical problems, but also to avoid local air movement speeds that are too low, which are unsatisfactory from a health point of view and can be unpleasant for some people. Ensuring rapid air mixing is also desirable at the end of the night before or upon the arrival of the first users in an area, whereas the desirable night stoppage to save energy may have led to a concentration of air heavier cold at the bottom of the zone and lighter less cold air at the top of the zone, called thermal stratification. Such a mixture in a zone having a height of several meters requires high local air displacement velocities in the upper part of said zone. These objectives are largely contradictory.

As illustrated in Figure 1, the ventilation device 1 of the building to be ventilated comprises a fan 2 and an air inlet duct 3 for receiving air from the fan 2. The air inlet duct 3 is arranged downstream of the fan 2. Upstream of the fan can be provided, an air heating/cooling unit 11. The air inlet pipe 3 in the building forms an outlet for the fan 2. air inlet 3 may have a rectangular cross-section with a width of the order of 0.5 to 1.5 m and a height of the order of 0.5 to 1 m. The ventilation device 1 comprises a distribution plenum 4 to distribute the air downstream.

The distribution plenum 4 is arranged downstream of the air inlet duct 3. The distribution plenum 4 is in the form of a rectangular parallelepiped. The distribution plenum 4 is connected by one side to the air inlet duct 3. The distribution plenum 4 can be made of sheet metal. Two thicknesses of galvanized steel sheet can be provided surrounding an insulating material, mineral or organic, forming an insulating lining, to form a flat panel. The panels can be assembled together by bending or by welding.

The distribution plenum 4 is provided with a plurality of air outlets. The air outlets are arranged on other sides of the distribution plenum 4, here on other lateral sides. Each air outlet comprises a cylindrical skirt and a plurality of air diffusion ducts 5. The cylindrical skirt is integral with the distribution plenum 4. The skirt is made of sheet metal. The skirt has the shape of a cylinder of revolution with a diameter greater than the length of said cylinder.

Each air diffusion duct 5 is fluidically connected to one of the outlets. The connection between the air diffusion duct 5 and the outlet is sealed to avoid loss of flow.

Each air diffusion duct 5 comprises an air diffusion portion provided with at least one vent 6 forming a perforated duct zone. The vent 6 can take the form of a perforation in a perforated wall. Vent 6 can also be in the form of a diffusion grid. The vents 6 are shown in thick lines in Figure 1. In the air diffusion duct 5 may be provided at least one connecting portion with a sealed wall to conduct the air flow from upstream to downstream.

At least one pressure sensor 7 is arranged in one of the air outlets. More generally, a pressure sensor 7 is arranged in each of the air outlets, see FIG. 6, or in each of the air outlets except one, see FIGS. 2 to 5, insofar as the pressure in an outlet of air alone devoid of pressure sensor 7 can be determined from the pressures measured by the pressure sensors arranged in the other air outlets.

Each pressure sensor 7 is fixed to the skirt of said air outlet supporting said pressure sensor 7. Each pressure sensor 7 can be screwed into or glued by adhesive to said air outlet. Each pressure sensor 7 is equipped with a wired or wireless communication output.

In the distribution plenum 4 is arranged at least one shutter damper 8. Each shutter damper 8 is arranged at least in each air outlet equipped with said at least one pressure sensor 7. The shutter damper 8 can be in the form of a parallelepiped-shaped body. The shutter damper 8 may comprise a rectangular frame forming a central passage and a plurality of flaps movable between an open position and a closed position. The shutter damper 8 is fixed in the distribution plenum 4 to an external wall. The shutter damper 8 is arranged across the opening of the air outlet. The shutter damper 8 is mounted in contact with a vertical wall of the distribution plenum 4.

The shutters can be tilting. The shutters can be sliding compared to fixed shutters. In the closed position, the shutters prevent air movement through the shutter damper 8. In the open position, the shutters allow air movement through the shutter damper 8 with low losses. The shutter damper 8 includes an actuator active on the shutters to move the shutters between the open position and the closed position and vice versa. Here, the shutter damper 8 is mounted on the inside of the distribution plenum 4. The shutter damper 8 is mounted upstream of the pressure sensor 7 of the corresponding air outlet. Thus, the operation of the shutter damper 8 is controlled for each air outlet equipped with said at least one pressure sensor 7.

The building ventilation device 1 comprises a control unit. The control unit is configured to receive pressure information coming from the at least one pressure sensor 7. The pressure information coming from the pressure sensor 7 can be transmitted by a wired or radio link to the control unit . The control unit is configured to send a setpoint to the at least one shutter register 8. The setpoint information from the control unit can be transmitted by a wired or radio link to the shutter register 8. The communication link can be common to a pressure sensor 7 and to a neighboring shutter damper 8 or to pressure sensors and to shutter dampers of the same distribution plenum 4. The control unit and the fan 2 are connected by a control link to control fan 2.

In a first embodiment, the fan 2 delivers an air flow in the air inlet duct 3 bringing the air flow into the distribution plenum 4 distributing the air flow between several diffusion ducts d air 5 by means of registers controlled by the control unit. The pressure is measured in the air diffusion ducts 5 by the pressure sensors. The control unit has information relating to the pressure in each air diffusion duct 5 and is thus capable of controlling the closing registers to obtain a dynamic distribution of the air.

In a second embodiment, a plurality of distribution plenums 4 are provided, arranged downstream of the air inlet duct 3. A first distribution plenum 4 is connected to the air inlet duct 3 and supplies other distribution plenums 4 and so on, the number of stages of distribution plenums 4 being limited only by the pressure drops. One of the air outlets of the first distribution plenum 4 can be connected to a downstream pipe 9 leading to at least one other distribution plenum 10, shown in dashed lines in FIG. 1. The first distribution plenum 4 can be type illustrated in Figure 6, in particular with an open face towards the downstream pipe.

In a third embodiment, a plurality of distribution plenums 4 are provided, each arranged downstream of an air inlet duct 3, downstream of the fan 2. The fan 2 supplies several air inlet ducts mounted in parallel.

In a fourth embodiment, a plurality of fans 2 are provided, for example two, supplying a distribution plenum 4, of the model illustrated in FIG. 6, disposed downstream of several air inlet ducts 3, each in downstream of one of the fans 2. Each fan 2 supplies an air inlet duct opening into the common distribution plenum 4.

In general, the pressure sensor 7 disposed downstream of the shutter damper 8 makes it possible to have a pressure value corresponding in a realistic manner to the flow rate of the air diffusion duct 5 disposed downstream of said shutter damper 8. A pressure/flow chart, if necessary integrating other parameters, can be established by measurement, by simulation or even by learning. Because the measured pressure is the pressure corresponding very directly to the air flow in the air diffusion duct 5, the control unit is able to control the distribution of the air flow much more precisely and less sensitive to faults or errors. The installation is thus more robust in operation and offers increased comfort.

Claims (7)

Building ventilation device (1), comprising an air inlet duct (3) for receiving air downstream of a fan (2), a distribution plenum (4) arranged downstream of the duct air inlet (3) and provided with a plurality of air outlets, each air outlet comprising a cylindrical skirt, a plurality of air diffusion ducts (5), each fluidly connected to one of the outlets, each air diffusion duct (5) comprising a perforated duct area, at least one pressure sensor (7) disposed in one of the air outlets and fixed to the skirt of said air outlet, at least a controlled shutter damper (8) arranged in each air outlet equipped with said at least one pressure sensor (7), the shutter damper (8) being mounted upstream of the corresponding pressure sensor (7), and a control unit configured to receive pressure information from the at least one pressure sensor (7) and to send an instruction to the at least one shutter register (8). Building ventilation device (1) according to claim 1, comprising a plurality of pressure sensors each disposed in one of the air outlets and fixed to the skirt of the corresponding air outlet. Building ventilation device (1) according to Claim 1 or 2, in which the distribution plenum (4) has a rectangular parallelepiped shape, with at least one side connected to the air duct to receive air downstream of the fan (2), at least one side provided with at least one air outlet, and at least one solid side, the plenum having walls each forming one of the sides outside the air outlets or air inlet , said walls comprising several layers. Building ventilation device (1) according to one of the preceding claims, in which the distribution plenum (4) is made of sheet metal lined with insulating material. Building ventilation device (1) according to one of the preceding claims, comprising said fan (2) downstream of which the air inlet duct (3) is arranged. Building ventilation device (1) according to one of the preceding claims, comprising a plurality of distribution plenums (4) arranged downstream of the air inlet duct (3), a first distribution plenum (4) being connected to the air inlet duct (3) and supplying the other distribution plenums (4). Building ventilation device (1) according to one of Claims 1 to 5, comprising a plurality of distribution plenums (4) each arranged downstream of an air inlet duct (3), downstream of the fan (2).