FR2732413A1 - Pump for clearing urban air - Google Patents

Abstract

There are greater than 100 fans arranged around and within the area to be treated. The machines generate a flow of the polluting fluid, which, after the fluid is mixed with the surrounding atmosphere, causes the polluting fluid to be driven in a specific direction, where the pollutant can be safely dispersed. The thermodynamic fan is typically a fan (7), which is driven by an electric motor (9), through a reduction gearbox (10) and an axial rotor (11). To avoid degradation of the machines over time due to weather problems, the machines are located within a nozzle shaped shroud, which serves to protect the machines and to act as silencers.

Description

 The present invention relates to a device for setting in motion very large quantities of fluids, at least one of the characteristic scales of which is greater than 100 meters.

 This device is, in particular, intended to allow the displacement of the atmosphere of urban agglomerations subjected to the accumulation of pollution under the effect of temperature inversion phenomena. It can also be envisaged to recover wind energy. Other applications according to the invention relate to the displacement of masses of liquid, such as for example in lakes, ports, lagoons or seas to treat local pollution problems or recover diffuse hydraulic energy.

 We know that large urban centers are often the seat of pollution phenomena resulting from the production of gaseous effluents sometimes loaded with aerosols from various sources, cars, district heating, factory chimneys, landfills in particular. When the so-called thermal inversion of the atmosphere occurs, the waste produced tends to stagnate in the atmosphere in the form of strata at a given level, especially since there is no wind. . Such a situation can become extremely critical and certain cities are known to be the seat of such situations which cause significant public health problems, which can go as far as the death of vulnerable people.

 Until now, those responsible for air management in cities have been content to carry out studies making it possible to describe the evolution of phenomena and therefore to judge the relevance of industrial or domestic establishments and to avoid or limit the emission of pollutants by various technological or regulatory measures. Certain projects of very large thermodynamic machines intended to move the air of the cities or to break the layers of inversion were the object or are still the object of studies, but their implementation was never carried out, because of the polluting acoustic, wind or aesthetic impact that they might generate.

 The same problematic is found in bodies of water which can also stagnate under the effect of temperature inversions, as in lakes, or under the effect of confinement, as in ports or lagoons. Again, the only tools commonly used are simulations and the treatment of pollution at source.

 The present invention relates to a device intended to move very large volumes of fluid initially contained in a space of which at least one of the characteristic dimensions is greater than 100 meters, this space itself being included in a space of even greater dimensions. , characterized in that it consists in using a very large number of thermodynamic machines, typically greater than 100, dispersed in the space to be treated and generating fluid flows which, after they are mixed with the surrounding fluid, entrain it in a preferred direction which is that towards which it is sought to move said large volumes of fluid.

 In a simplified approach to the problem, it is known that a particular fluid layer of an inversion mixes very poorly with the layers immediately above and below. It is therefore understandable that it is possible to slide it horizontally between its two neighboring layers provided that this is done without creating too much turbulence.

This practically excludes the use of very large fans whose diameter would be of the same order of magnitude as the thickness of the layer to be moved. On the other hand, by using in this fluid layer a very large number of small fans whose diameter is much smaller than that of the layer to be treated, these fans being distributed throughout the volume to be moved, it can be imagined that the turbulence induced by a single fan will not induce large vortices away from said fan and that the fluid layer, under the effect of this plurality of small distributed forces will move between its two neighboring layers without mixing with them. This multitude of fans will entrain the fluid without inducing very significant turbulence.

 Another advantage of using very small fans is that their performance is much lower than that of large fans. For fans of similar geometries, the total theoretical mass of the devices used, including that of the electric drive motors for the same aeraulic performance is inversely proportional to the square root of the number of fans. The number of fans is proportional to the square of their diameter. The total mass of the device will therefore be proportional to the diameter of the fans. We can see the spectacular saving of material achieved when the number of fans used is increased. This results in a significant drop in investment when the number of fans is such that they can be produced with modern series techniques. To these advantages is added the fact that small fans can be driven without requiring a gearbox by motors. commercial electrics. The machines are therefore much simpler to make and, therefore, less expensive. Finally, small fans can be produced in very large series using modern industrial techniques and therefore at very low unit cost prices.

 This same reasoning can apply to a situation of inversion in a liquid or more generally to the displacement of a liquid mass of given thickness.

 In the case of treatments of urban atmospheres, the presence of buildings and streets creates a very significant roughness which could hinder the movement of the air to be evacuated. The device according to the invention, the dimension of the fans constituting it is very small compared to that of a street or of a building makes it possible to avoid this drawback.

One can imagine that the elementary fans placed in a street all blow in the axis of said street, so that they generate by entrainment a channeled flow whose speed is controlled. We also imagine that by favoring for these elementary flows a general direction of flow in the desired direction of movement of the air mass, we can gradually replace the air in these streets by air from areas not initially polluted located outside the agglomeration. The arrangement of the fans and the direction and the power of the air flows in the different ways constituting the city could be the subject of a preliminary simulation study by means of mathematical models or tests in wind tunnel or in hydrodynamic tunnel.

These techniques are currently well mastered by specialists. In general, the optimized management of such a system would be done by means of a central computer taking into account the results of these tests, the topography of the city, the weather forecasts,
The time, the season, the production of pollution and many secondary influence parameters.

 These rotating machines could be used to deal with other situations in which large masses of fluid have to be moved. We can cite, for example, the treatment of cold areas at the bottom of valleys to avoid freezing of crops. Such situations can arise when the microclimates are modified by the presence of a highway or railway embankment which can hinder the circulation of air over a height of a few meters.

Other characteristics and advantages of the present invention will appear more clearly on reading the following description of several embodiments of
The invention given by way of nonlimiting examples. The description refers to the appended figures in which:
- Figures la and lb give a representation of the principle of the invention
in which thermodynamic machines are fans distributed in space
whose air we want to renew. The figure shows schematically the location of the fans on
various supports typical of street furniture. Figure 1b gives a view of one of the
fans.

- Figure 2 shows the evolution of an urban pollution cloud depending on whether
activates or not a device which is the subject of the invention.

- Figure 3 shows the directions of the artificial winds to create in a city
depending on whether you are in the upper part of the buildings or, on the contrary, in the streets
or sheltered spaces.

 The figure shows schematically an urban site I to clean up, characterized by the presence of various buildings and supports, collective buildings 2, individual houses 3, electric or telephone poles 4, traffic signs 5, places of worship 6 etc. All these supports carry small axial fans 7 which are directed in the direction in which one wishes to move the pollution. Because of their small size. these fans do not induce strong turbulence and their effect is only felt in the atmospheric layer in which they are located. Line 8 shows schematically the limit above which they have no influence and which is located at a height slightly higher than that of said layer. Figure 2b shows a fan 7 composed of an electric motor 9, d ' a rectifier 10 and an axial rot or gold 11. In order to avoid deterioration of the device due to bad weather, the fan unit is placed in a nozzle 12 serving at the same time as protection, acoustic filter and aerodynamic component . This nozzle is provided with protective grids 13.

 As an example, we will consider the dimensioning of a fan installation intended to move an air mass of 5 km in length, 5 km in width and 100 meters in height at a speed of I m / s. Aerodynamicists know that it is necessary to apply the momentum theorem to solve this problem.

The amount of movement q to create to horizontally move an air mass with density p of a vertical surface S of 500,000 m2 characterized by a height h of 100 m and a width L of 5000 m at a speed V according to a flow rate Q is equal to:
q = pQV
either, q = pSV2
or q = phLV2
If a number n of fans of diameter D producing a jet at the speed Vj are used to perform this operation, the quantity of movement to be produced by these fans to ensure the function is equal to the quantity of movement q desired.

The amount of movement caused by the fans is written: q = PS VJ2
It is your sum of the surfaces of the jets produced by the fans immediately at their exit. n being the number of fans and s their unit area, we therefore write:
q = npsV, 2
We therefore deduce that the cumulative surface S 'to be used is equal to:
V2
S = S
V,
As for the power to be used, it is equal to:
P = S '2 pV3
2
Or, again
P = S 1 pVjV2
2
In the example we have chosen, we deduce that, for a speed V of 1 m / s and a speed Vj of 10 m / s, the surface S 'is 5000 m2 and the theoretical power to be implemented 3,250 kW. The 100 m thick, 5 km wide air mass is then displaced in 1 hour over a distance of approximately 4 km. The mass of air set in motion is then several million tonnes.

 Typically, according to the invention, the number n of fans will be 25,000 and their unit diameter of 500 mm. Their theoretical unit power will be 130 Watts. The real power will be slightly higher taking into account the yields and friction.

It can be estimated at 200 Watts. These fans will preferably be distributed uniformly throughout the city, without this constituting an obligation.

 These figures show that such a project is feasible, despite the very large mass of air to be moved and that the solution object of the invention is particularly elegant and easy to implement, while not requiring investment very important.

 It will be noted that the setting to a higher speed can be done, either by multiplying the number of fans, or by multiplying their rotation speed in proportion to the desired speeds V. The first solution requires larger investments. The second involves the use of variable speed motors or variable incidence fans whose power will be proportional to the cube of the desired speeds. Thus to go from I to 2 m / s, without changing the equipment, it is necessary to double the fan speeds and multiply by 8 the power of the motors.

 FIG. 2 schematically shows a cloud 14 resulting from the accumulation of pollutants in an urban area in the absence of treatment. If the pollution is constant, the concentration of this cloud in the various species increases linearly as a function of time.

This can lead to a catastrophic situation. On the contrary, the cloud 15 is moved by the device object of the invention according to the arrows F0. The concentration of pollutants above the city then remains constant and the risk of disasters is reduced, the maximum concentrations being proportional to the reverse of the speed of the cloud. For a city of 7 km in length in the direction of movement of the cloud at Im / s, the maximum concentration at the point noted A in the figure, therefore at the exit of the city in the direction of movement of the cloud, would be that which we would have in the initially unpolluted fixed cloud after two hours
Figure 3 gives the plan view view from above of a city 1 and its main streets 16. The general direction desired for flows above the city is indicated by the arrows F0. The fans located on the roofs of buildings and in open areas will therefore blow in this direction F0. On the other hand, the fans located in the streets of the city will blow more or less strongly in the direction F1 of the said streets and in suitable directions in order to empty them of the pollution that they contain towards cleared outlets 17 in which the direction of the wind at ground will be that of the wind above the buildings, and therefore given by the general directions F0.

The assembly will generally be controlled by a central computer.

 All these devices and application examples are given by way of illustration of the invention and cannot be considered to be exhaustive, alternative arrangements which can be developed by those skilled in the art.

Claims (6)

CLAIMS.  1. Device intended to move very large volumes of fluid initially contained in a space of which at least one of the characteristic dimensions is greater than 100 meters, this space itself being included in a space of even greater dimensions, characterized in that '' it consists in using a very large number of thermodynamic machines 7, typically greater than 100, dispersed in the space to be treated and generating flows of fluid which, after they are mixed with the surrounding fluid entrain it in a preferred direction which is the one towards which it is sought to move said large volumes of fluid.  2. Device according to claim N 1 characterized in that the volume to be treated is the atmosphere of a city I and in that the fluid surrounding the atmosphere located above and around said city, the thermodynamic machines being fans 7 small.  3. Device according to claims N l and 2 characterized in that the direction in which the fans blow depends on the topology of the terrain and the presence of buildings.  4. Device according to claim N "1 and 2 characterized in that the fans are installed on buildings or pre-existing supports.  5. Device according to any one of the above claims, characterized in that the fans used to clean up said city I are controlled by a central computer from meteorological data.  6. Device according to claim N l characterized in that the fluid to be displaced is water and that the larger space is a body of natural water, such as a lake.