ITMI20070625A1 - PLANT AND METHOD FOR THE REMOVAL OF AT LEAST ONE POLLUTANT FROM A FLUID IN A GASEOUS STAGE - Google Patents

Description

DESCRIPTION

"PLANT AND METHOD FOR THE REMOVAL OF AT LEAST ONE POLLUTANT FROM A FLUID IN THE GASEOUS PHASE"

The present invention relates to a method and the relative plant for the removal of at least one polluting substance from a fluid in the gaseous phase.

In particular, the object of the invention is to remove polluting substances from an air flow, such as solvents, dispersed in the form of vapors, gases, fumes, gaseous phases or even micro-drops, allowing to obtain an air flow out of the system. that complies with the regulations in force for emissions into the environment. As is known, there are both Italian and international regulations that impose limits on the presence of pollutants within the air flows or gaseous flows that are released into the environment.

A new legislation has recently been approved which has significantly lowered these limits by substantially harmonizing them at an international level. Today there are systems capable of allowing the control of gaseous emissions of pollutants into the atmosphere and in particular the most common types are post-combustion technologies and activated carbon technologies.

First of all, it should be noted that many industrial sectors provide for processes (such as the painting of wood, metals, plastics, the printing processes whether silk-screen, flexographic or rotary, the pickling processes for preparation for painting or even certain pharmaceutical processes for the extraction of active ingredients) that make extensive use of chemical substances and in particular of solvents which, during or at the end of the process, are dispersed in the air flow which is removed from the processing area and which must be treated before being released into the atmosphere in order to comply with environmental regulations.

The post-combustion technology basically involves the presence of an incinerator or more incinerators that burn the pollutants present in the gaseous stream before being released into the atmosphere.

This plant, in addition to having a rather high construction cost, also has high maintenance costs in particular if it is not possible to obtain an autothermal operation, or if the combustion must be constantly fed.

In addition, these devices have the further problem of generating secondary pollutants (for example C02 or NOx) or even dioxins where sufficient temperatures are not reached.

However, even the activated carbon technology that allows the absorption of pollutants has some drawbacks and / or operational limits.

In particular, it should be noted that the carbons generally absorb about 1/10 of their weight in solvent and therefore where there are important flows of pollutants there is a very rapid depletion of the depolluting capacity of the activated carbon that must be regenerated, for example with expensive operations. of external regeneration.

On the other hand, even the use of activated carbon plants with stripping technologies entails the need to create rather complex chemical plants with costs comparable, if not even higher, to those of the heat destroyer mentioned briefly above.

In order to at least partially avoid the aforementioned drawbacks, the Applicant has designed and built a plant for the removal of at least one pollutant substance from an air flow in which there are three modules, each having at least one thermal jump device maintained at temperatures lower than that of the air containing the pollutant to generate a temperature variation and cause condensation and / or freezing of part of the humidity and / or pollutant contained in the fluid passing through. Each of the three modules then included at least one droplet separator downstream of the thermal jump device along the direction of advancement of the air, designed to collect drops or micro-drops present in the flowing flow.

Such a plant, while performing in an excellent manner the tasks for which it was designed, nevertheless showed yields that varied over time and which were completely unsatisfactory when the plant was fully operational.

Therefore, the object of the present invention is to substantially solve all the aforementioned drawbacks.

The main purpose of the invention is to provide a plant and a methodology for the removal of polluting substances from a gaseous flow, and in particular from an air flow, which allows as much as possible to contain the costs of both the plant and maintenance of the system itself.

It is also an important objective to allow the optimal operation of the system in all its operating phases, avoiding significant drops in yield.

A further objective of the invention is to provide a device that can be used to remove a wide range of pollutants and therefore can be adapted to different industrial sectors while always allowing compliance with the standards.

A further purpose of the invention is also to allow compliance with the standards during all stages of industrial processing, or even during any peaks in the introduction of pollutants into the air.

Finally, a further object of the invention is to provide a device and a methodology for the removal and recovery of pollutants that can adapt without particular structural changes to the most diverse operational needs, or to the presence of flows with a lot of pollutant or with little polluting substance, or even to the treatment of large volumes of air or smaller volumes.

This and other purposes, which will appear better in the course of the present description, are substantially achieved by an apparatus and by the related procedure for the removal of at least one pollutant from a fluid in the gaseous phase according to what is described in the attached claims.

Further characteristics and advantages will become clearer from the detailed description of a preferred, but not exclusive, embodiment of a process and related apparatus for the removal and recovery of polluting substances according to the present invention.

This description will be made hereafter with reference to the accompanying figures, provided for indicative and therefore non-limiting purposes only, in which:

Figure 1 schematically represents a plant for the removal of a polluting substance from a fluid in the gaseous phase according to the invention;

Figure 2 illustrates a block diagram of a further embodiment of the invention; And

Figure 3 shows the plant of Figure 2 in a more detailed view.

In the figures, the system that allows the purification of the polluted fluid 3 in the gaseous phase is designated as a whole with reference 1.

This plant will in particular be destined to operate on the gaseous discharges of various types of processing.

In particular, it will be suitable, for example, for treating the discharge flow of painting plants, plastic material processing plants, printing plants, pickling plants, but also plants in the pharmaceutical or cosmetic sector.

Obviously, the aforementioned sectors are just some of those in which air flows loaded with pollutants such as solvents are generated.

Again purely by way of example, the regret which will be described hereinafter will be predisposed to the removal and recovery of solvents such as alcohols, ketones, aromatics, esters or aliphatics.

Obviously, the removal referred to in the claims is able to operate not only with the solvents mentioned, but also with additional pollutants not listed in the attached table, (provided for illustrative purposes only)

Returning to figure 1, the flow of fluid in the gaseous phase, which in general will consist of air and at least one pollutant (or more than one) present in the form of vapor, micro-drops and / or fumes inside this flow will be forced. to enter the plant through a suction mouth 2 to pass through the plant itself along the direction of advance 6 of the flow.

The system is equipped with at least one device 8 to generate a flow of air inside the system itself.

In general, this flow is already created with its own aspirations (other than those of the plant in Figure 1) within the area in which the vapors of polluting substances are generated precisely to ensure that the air is removed from this environment. In any case, the plant is equipped with this additional device 8 due to the fact that it causes strong pressure drops during the flow crossing and therefore, in order not to depress the internal suction of the company, one or more fans to fully recover the additional pressure loss caused by the system itself.

As can be seen from the accompanying figures, there are also control means 20 intended to control the device 8 in order to be able to vary the flow of fluid passing through the plant, in particular at least as a function of a control parameter of the fluid itself, such as it will be better clarified later in the explanation of the operation of the system.

Said control means 20 may comprise different types of known systems, such as a microcontroller or CPU, a PLC, or other structures capable of receiving a signal which is a function of the control parameter at the input and generating in turn a command for the fan / and suction (device 8) in order, for example, to vary the drive torque, the rotation speed rather than the inclination of the blades, consequently varying the flow of fluid passing through the system.

In general, the air flow entering the system in the example of Figure 1 will have exactly the temperature at which it leaves the processing area inside the company.

In the case of flexographic printing processes, the air can also reach temperatures around 50 °, as well as in the case of aluminum lamination processes; vice versa, in the presence of mechanical washing, a flow of air at room temperature could be generated at the entrance.

In any case, the regret in figure 1 is not generally responsible for the heat treatment of the air before the removal of pollutants; in particular, it is not designed to vary the temperature of the inlet air and it will therefore be necessary to change the power and operating temperatures of the various devices according to the inlet air temperature.

Obviously in exceptional cases, if it is absolutely necessary to lower the temperature of the air entering the system, an exchanger with well water or similar equipment of a known type of fairly low cost could also be used.

Again with reference to the first embodiment, the incoming air first of all passes through a flow humidifier 7 selectively designed to transfer a certain substance in the flow in the gaseous phase as it passes through. In particular, the humidifier used is of the adiabatic type for coalescence of the type known on the market today.

The adiabatic humidifier 7 is actually not always essential for the operation of the system itself and its use essentially depends on the conditions and type of the incoming air flow.

For example, in flows that are too little polluted, problems are created (also depending on the solvents used) since the same solvents have a vapor pressure curve that varies as the temperature varies.

Obviously, the purpose of the plant is to bring the vapor pressure to values close to zero (i.e. aiming at the complete liquefaction of the solvent). In reality, compliance with the parameters in force for release into the environment are achieved by obtaining extremely low values of the vapor pressure around 0.001 which allow, even with very volatile solvents (for example certain ketones or alcohols), to remain within the standards in force. .

However, it should be noted that the variation of the vapor pressure with the temperature also depends on the saturation curve of the product. Therefore, if there are high percentages of pollutant in the flow, greater abatements are obtained; vice versa, where the flows have slight quantities of pollutant, it is necessary to drop the temperature much more than in situations with higher percentages.

For example, when working with isopropyl acetate it is sufficient to drop temperatures by about - 30 ° with saturated flows (2000-3000 milligrams per normal meter 3), vice versa in the presence of only 50-100 milligrams per normal meter 3 it would be necessary to go down to temperatures of about -85 ° with evident energy problems, frosting and in general the need for extremely complex cryogenic systems suitable for reaching such temperatures.

In this situation the adiabatic humidifier 7 can be used to introduce further pollutant into the flow so as to decrease the temperatures necessary for its removal.

Obviously, even in situations of extremely high quantities of pollutants and therefore such as to generate difficulties in their sufficient drainage, it is necessary to introduce an intermediate medium into the flow that allows to obtain the necessary abatements.

In general, an azeotrope will be created in the flow which can more easily be drained.

The same situation will also occur in the presence of extremely volatile or very hot polluting products such that the vapor pressure is extremely high and such as not to allow these products to freeze. In this situation it may be appropriate to use the adiabatic humidifier 7 to introduce carrier substances such as for example water or alternatively the 2,2,4-trimethyl-1,3-pentanediol monoisobutyrate which allow, by creating suitable azeotropes, to raise the freezing temperatures so that pollutants can be removed.

In the presence of methyl chloride, which solidifies at -30 °, it is generally not necessary to add any additional carrier through the adiabatic humidifier.

A further situation in which the adiabatic humidifier can be used is given by the processes in which pollutant peaks are generated in certain working conditions.

In this case, the adiabatic humidifier 7 will be used only and exclusively when the air flow is extremely loaded with pollutants while it will be deactivated when this flow returns to have a lower percentage of pollutants.

Obviously the adiabatic humidifier will be connected to a pump for wetting and coalescing the screens. This pump can be activated via a timer (i.e. the screen is wetted for a certain period of time every certain time interval) or also connected to a pollutant detector which automatically decides the activation and shutdown of the pump itself. Still observing the plant in figure 1 and immediately downstream of the adiabatic humidifier 7 there is therefore a thermal jump device 4 maintained at a temperature lower than that of the fluid flow in the gaseous phase 3, generally a very important Δt.

The device is crossed by the flow in the gaseous phase and causes condensation and / or freezing of at least part of the humidity and / or part of the polluting agent.

It is evident that the first thermal jump coil 4 crossed will mainly freeze water, as well as the part of the pollutant that is mixed with the water itself.

Obviously, this exchanger will also force part of the vapors, fumes or micro-drops to condense, drops that will coalesce downwards and will contribute more to absorb part of the pollutants arriving in the flow.

It is also evident that where substances extremely miscible with water are present (for example acetone) the first battery will also extract an important part of the polluting agent, vice versa where the solvent is not very miscible with water (for example chloride of methylene) the first battery will basically serve to significantly lower the humidity of the air flow.

Obviously the geometry and the exchange surfaces of the thermal jump device 4 must be studied according to the dimensions of the system and the air and pollutant flows passing through, however in general they must be studied in such a way that the flow in the gaseous phase it passes through the thermal jump device 4 with an average speed between 1 and 2 m / s and preferably at the limit of the heat exchange between 1.2 and 1.5 m / s.

At this point it should be noted that obviously the ice will tend to occlude the coils over time and therefore any predetermined time interval (for example 30-50 minutes; however this time interval will obviously depend on the operating conditions and the size of the system) will be it is necessary to release the thermal jump device 4 from the system in order to defrost it using, for example, a jet of water.

In general, a temperature difference of about 15 ° could be sufficient for the first freezing / condensation operation. In reality, the temperature difference used is more important even if in general, due to the enthalpy of the water, the first heat exchange coil generally does not drop beyond -5 / -10 °, however, generally working below 0 °.

Immediately downstream of the heat exchange device 4 there is at least one droplet separator 5 designed to collect drops or micro-drops already present in the flow or that have been created during the passage through the adiabatic humidifier and / or the thermal jump device 4.

In general, this drop separator 5 is of a turbulent nature to allow better collection of the droplets and is kept at a temperature substantially equal to that of the thermal jump device to increase its efficiency.

In this regard, the droplet separator 5 is made of metallic material such as steel and is directly connected to the thermal jump device itself so as to remain cold (in other words it acts as a further condensation medium).

Alternatively, it is possible to use a drop separator of a nature other than the turbulent one, such as for example ceramic or sintered ceramic droplet separators.

In general, the flow humidifier 7, the thermal jump device 4 and the droplet separator 5 define a first module A of the system; in general regret itself includes at least two modules A, B and in general three modules A, B, C sequentially committed to each other to be crossed by the flow to be treated.

Obviously, the subsequent modules are structurally completely similar to the one previously described and will only change the conditions of the inlet and outlet air flow and the operating temperatures.

In general, it will be the second module that will have the greatest problems with creating ice.

Vice versa, the third module will be crossed by substantially dehumidified and already cold air and the third thermal jump device 4 will work with temperatures for example between -25 ° and -35 °, being able to reach temperatures of -100 °.

Obviously, refrigeration means 9 are provided which are suitable for generating the appropriate low temperatures in the thermal jump devices 4.

In general, these means will consist of a compressor and a circuit that uses freon as the working gas.

Moving on to observe the embodiment of the system shown in Figures 2 and 3, it is first of all noted, immediately downstream of the means 8 for generating the air flow inside the system itself, the presence of a heat exchange unit 10 in general consisting of an air-to-air exchanger,

This heat exchange unit 10 can be by way of example a tube bundle or finned pack exchanger or other to allow the thermal interaction between the flow of polluted fluid 3 entering and a part of the low temperature flow leaving the plant after being been purified. In this way, the heat exchange unit 10 will act as a heat recovery unit to allow energy recovery to be obtained and will begin to lower the temperature and create condensation (at least with reference to humidity and water vapor) of the polluted fluid flow 3 that you want to treat.

A flow mixer 11 is also provided immediately downstream of the heat exchanger.

In particular, the flow of polluted fluid 3 will be physically mixed with a part of the flow of cold air leaving the system as shown in figure 2.

In particular, the two flows will be placed in contact with each other in an area 12 immediately upstream of the flow mixer 11 and then pass through a mixing chamber which will allow optimal mixing.

For example, the flows can be mixed in a 1 to 1 ratio and the overall flow will cross a series of baffles or surfaces that act as barriers to condensation or freezing of moisture / water vapor as well as part of the polluting products to be retained.

It is evident that this process will involve the creation of ice at the surfaces of the mixer 11 and that therefore periodic defrosting cycles will be required to allow the percolation of solidified products.

It should also be noted that the air flow leaving the system and which will be mixed in the inlet area 12 may have temperatures even around -70; - 80 °.

From here the flow of polluted fluid 3 enters an air cooling battery 13 shown in figure 2 and detailed in figure 3.

This air cooling battery 13 may be equivalent to a module A of the type described above, and in detail will comprise at least the aforementioned thermal jump device 4 and the droplet separator 5.

However, in the embodiment illustrated in Figure 3, various elements will be present along the direction of advancement 6 of the air flow.

In particular, a first space 14 is provided which can be used for any accessories to be inserted in the system.

Immediately downstream there is a denebulizer 15 immediately followed by a deflector 16.

From here the flow enters the thermal jump devices 4 of the type described above and then meets the droplet separator 5 also of the type previously analyzed.

Optionally, additional usable space can be provided for any accessories 17.

The adoption of the heat exchange humidity 10 and of the flow mixer 11 will help with the appropriate refrigeration means then described to reach temperatures in the thermal jump device even of - 100 °

The dry air clean from pollutants and at low temperature can be partially tapped (for example by means of a tapping and recirculation fan 18) to be sent to the inlet area 12 and then further mixed with the flow of polluted fluid 3 entering the device ,

The part of clean air not used for recirculation will be sent to the heat exchange unit 10 to perform the functions described above and then will be introduced into the environment.

It should be noted that the use of the heat exchanger 10 and the mixer 11 will allow for an important energy recovery as a lot is the energy required by the system when there is a need to drop a lot with the temperatures.

It is evident that obtaining a good energy recovery allows a considerable recovery of costs and therefore gives competitiveness to the system.

In this regard, it should be noted that the system illustrated in figures 2 and 3 will be able to operate in the area of the thermal jump device 4 at temperatures that will even reach - 100 ° with a flow of clean air at the outlet (OUTLET) with temperatures between - 70 and i - 90 °.

It should also be noted that in systems of the type shown in figures 2 and 3, the method for generating the cold is also extremely important.

Obviously temperatures up to -100 ° can be used technologies that exploit liquid nitrogen or cryogenic systems of known type.

In the particular case, the use of refrigeration compressors for medium temperatures (about - 50 °, as operating temperature) of the screw type or even single or two-stage pistons with the use of R 507 freon gas was chosen.

In order to obtain cold with this type of compressor, a liquid receiver is placed downstream of the compressor which receives the freon leaving the compressor at high pressure and extremely hot.

Thanks to an internal coil for the heat exchanger, the outgoing freon is cooled with freon from the same circuit that comes from the expansion in the battery in the cold production cycle (at temperatures of about - 70 °).

In this way I get the following advantages.

A first cooling of the freon that goes into the circuit and also the heating of the freon that instead enters the compressor (in this way the freon entering the compressor will be at a temperature not more than - 70 °, but at temperatures of - 30 or - 40 ° ).

So hoping the compressor (volumetric pump) will have a differential pressure that allows it to give cooling power.

Downstream of the liquid receiver, the high-pressure hot freon begins to be cooled to reach the lamination organ.

In particular, the freon can be brought from about 70 ° up to temperatures around 5-10 ° which correspond to pressures of about 8 bar.

In detail, a pre-expansion phase is carried out with a plate exchanger on one part of the freon so that the latter is expanded and mixed with the other to cool it so as to arrive in lamination at temperatures around - 20 °.

By proceeding in this way it is possible to laminate the freon R 507 up to pressures of about 0.45 bar so as to reach temperatures between - 80 and - 90 °.

It should also be noted that regret will also include at least one collection tank for the pollutant and for the water separated from the flow (not shown).

The tank allows for the possible at least partial separation of the water and the pollutant by decanting.

In particular, most solvents are substantially immiscible with water and therefore three phases are generated in the tank by decantation, a heavier phase on the bottom of the container consisting of the heaviest pure substance, an interference of dimensions depending on the miscibility of the liquids and a third upper phase consisting of the less heavy liquid in pure form.

For example, having a mixture of water and isopropyl acetate, the latter which is lighter will be found at the top in this tank, while the water will collect towards the bottom, generating an intermediate interference zone.

At the bottom there will be at least one outlet to allow the heavy substance to be discharged.

Using a suitable electrical conductivity / resistivity sensor applied to the outgoing fluid, it will be possible to calibrate this probe on the heavy phase; when the conductivity begins to change, it means that part of the interference is being drained and therefore the output can be selectively closed according to the signal detected by the sensor.

In this way it is possible to separate the heavy phase from the light one and it becomes necessary to treat only the interference part.

When the system is switched on, or at each restart after a certain time of non-operation, the device 8 (i.e. the fan / fans) generates the appropriate suction so that the pressure difference created allows the generation of a flow to the inside the plant itself, overcoming the pressure drops in the machine.

The control means 20 will begin to receive the signal (s) coming from the suitable sensors 21 suitable for measuring the fluid control parameter (s). In general, the preferential control parameter will consist of the temperature of the fluid passing through the system, at least in correspondence with the module where the air reaches the lowest temperature.

Obviously it will be possible to have more than one temperature measurement in the various areas of the plant of interest.

In addition or alternatively, it will be possible to provide for the measurement of other parameters of the fluid such as for example its speed in crossing or also the pressure or humidity.

Referring in particular to the temperature in the last stage C of the plant, it is evident that it will start from a condition in which it is substantially equal to the fluid inlet temperature, gradually lowering up to the operating temperature in the steady state condition.

The temperature variation of the fluid in the gaseous phase passing through the system involves a considerable variation in the volume passing through.

In particular, the presence of an important temperature variation (ΔΤ) leads to volume reductions even higher than 50% with respect to the volume of the inlet fluid.

It is therefore evident that the optimal suction conditions at the start of the plant will be completely different from the optimal suction conditions in the steady state condition.

If appropriate measures are not adopted to remedy the above, the overall performance of the system would suffer a considerable degradation.

In this situation, the control means 20 are active on the device 8 capable of generating the flow inside the plant to change an operating parameter, so as to take into account the variations in the volume of the gas inside the plant itself.

In particular, as the temperature decreases inside the various modules, the control means 20 will send a signal to the fan, varying for example the drive torque.

The variation of the drive torque of the fan allows the system to be kept in operating conditions at optimum efficiency, keeping the pressure difference generated also in the best operating range. It is evident that it will be possible to decide to intervene on other operating parameters of the fan, such as its rotation speed or the orientation of the thrust blades, always in order to achieve the purposes outlined above.

Finally, it should be noted that the air flow leaving the system will be at a low temperature and will be a completely dry flow.

The latter can be suitably heated, for example, by exploiting the heat produced by the refrigeration means for the generation of low temperatures and then be reused for drying artifacts or certain closed environments where the processing takes place in such a way as to be able to recover part of the heat. which otherwise would be lost by dissipation.

Alternatively, it will be possible to use the heat created by the pump to generate the cold in order to heat the air used for heating the internal environment of the company, thus being able to recover part of the energy consumed.

It should also be emphasized an important possible use of the systems described above in particular in the presence of large flows of polluted fluid 3 (for example flows over 15,000 normal / m <3> per hour).

With flows of this nature, electricity consumption becomes extremely high and regret may not be of convenient use and / or the current available is not sufficient.

In this case it is possible to use common removal and filtering machines that exploit adsorption on activated carbon filters using in particular two or more activated carbon beds.

Conversely, the system shown in figures 1, 2 or 3 can be used with a reduced air flow (500-2000 normal / m <3> per hour) to obtain the desorption of the spent activated carbon.

In particular, by removing the bed of activated carbon that has been exhausted due to the presence of pollutants, it will be possible to obtain its desorption by passing through them a flow of air without humidity (in this way the activated carbon will have a longer residual life as they suffer humidity) and then using the plant in accordance with the invention to remove the pollutants from the flow coming from the activated carbons,

Moreover, by working at low temperatures on the coals, dangerous isothermal reactions are also avoided.

The invention achieves important advantages.

First of all, regret realized in accordance with the invention is simpler to build and manage than known techniques that involve post combustion or the use of activated carbon.

The plant itself is suitable for the recovery of a wide range of solvents and pollutants in such a way that it can be used for numerous types of processing.

Thanks to the presence of active control means on the suction fan, it is possible to guarantee optimal operating conditions in all phases of the transient system from start-up to steady state conditions,

Furthermore, the control means operate independently of the optimum temperatures for the removal of the polluting agents and of the velocities and masses of fluid entering the plant itself.

Moreover, it may be envisaged to use one or more of the modules inserted in the system itself by activating only and exclusively among the devices inserted in it those strictly necessary to comply with current regulations.

By way of example it will be possible to use none, only one or two or more of the adiabatic humidifiers according to the flows and the necessary needs.

Finally, the system can be managed with simpler and less expensive operations than the systems on the market today.

Claims (32)

CLAIMS 1. Plant for the removal of at least one pollutant from a gas phase fluid flow, comprising: - a suction mouth (2) for the entry of a flow of fluid in the gaseous phase (3) containing at least one pollutant; - at least one thermal jump device (4) maintained at a temperature lower than that of the gas phase flow (3) to generate a ΔΤ, said device (4) being crossed by the gas phase flow and causing condensation and / or freezing of part of the humidity and / or pollutant contained during the crossing; - at least one droplet separator (5), preferably placed downstream of the thermal jump device along a direction of advance (6) of the flow in the gaseous phase (3), designed to collect drops or micro-drops present in the flowing flow; And - a device (8) for generating a flow of fluid in the gaseous phase through at least the thermal jump device (4) and the droplet separator (5); characterized in that it further comprises control means (20) adapted to control the device (8) for varying the flow of fluid passing through the plant as a function of at least one control parameter of the fluid itself. 2. Plant according to claim 1, characterized in that it further comprises at least one flow humidifier (7) selectively designed to transfer, preferably by coalescence, a certain substance into the flow in the gaseous phase (3) passing through. 3. Plant according to claim 2, characterized in that said humidifier (7) is an adiabatic humidifier, preferably an adiabatic humidifier for coalescence. 4. Plant according to claim 2, characterized in that said humidifier (7) is placed upstream of the thermal jump device (4) along the flow direction (6). 5. Plant according to any one of the preceding claims, characterized in that the device (8) for generating a flow of fluid in the gaseous phase through the thermal jump device (4) and the droplet separator (5) is defined by one or more fans and is preferably capable of creating at least one pressure increase in the flow equal to the pressure drops of the flow through the equipment. 6. Plant according to claim 1, characterized in that the control means (20) are active on said fan to vary an operating parameter thereof and preferably the drive torque. 7. Plant according to claim 1, characterized in that it comprises at least one sensor (21) suitable for measuring the control parameter, the control parameter being a temperature of the flowing fluid. 8. Plant according to any one of the preceding claims, characterized in that the thermal jump device (4) is designed to generate a ΔΤ with the flow of at least 15 °, the operating temperature of the device (4) preferably being lower than 0 ° and even more preferably between 0 and -10 °. 9. Plant according to any one of the preceding claims, characterized in that the gas phase flow passes through the thermal jump device (4) with an average speed between 1 and 2 meters per second and preferably between 1.2 and 1.5 meters per second. 10. Plant according to any one of the preceding claims, characterized in that the droplet separator (5) is of the turbulent type or alternatively of the ceramic type and is in particular maintained at an operating temperature substantially equal to that of the thermal jump device ( 4). 11. Plant according to claim 10, characterized in that the droplet separator (5) is made of metallic material, for example steel, and is directly connected to the thermal jump device (4). 12. Plant according to any one of the preceding claims, characterized in that it also comprises a heat exchange unit (10) placed upstream of the thermal jump device (4) along a flow direction (6). 13. Plant according to any one of the preceding claims, characterized in that it also comprises a flow mixer (11) placed upstream of the thermal jump device (4) along a direction of advancement (6) of the flow and suitable for mixing the flow of fluid (3) with a lower temperature fluid flow. 14. Plant according to claim 2, characterized in that the flow humidifier (7), the thermal jump device (4) and the droplet separator (5) define a first module (A) of the plant (1) , the plant (1) comprising at least two modules (A, B) and preferably three modules (A, B, C), sequentially engaged to each other. 15. Plant according to claim 14, characterized in that the second thermal jump device (4) has an operating temperature in operation comprised between -20 and -30 °. 16. Plant according to claim 15 characterized by the fact that the third thermal jump device (4) has an operating temperature in operation comprised between -25 ° and -35 °, and can even reach up to -100 °. 17. System according to any of the preceding claims, characterized by the fact that its interior is thermally insulated from the external environment. 18. Plant according to any one of the preceding claims, characterized in that the flow of fluid in the gaseous phase (3) is mainly defined by air. Plant according to any one of the preceding claims, characterized in that the polluting substance is a solvent, for example an alcohol and / or a ketone and / or an aromatic and / or an ester and / or an aliphatic. 20. Plant according to any one of the preceding claims, characterized in that it further comprises refrigerating means (9) for generating the appropriate low temperatures in the thermal jump devices (4). 21. Plant according to any of the preceding claims, characterized by the fact that it includes at least one tank for collecting the pollutant and water separated from the flow, said tank also allowing the possible at least partial separation of water and pollutant by decanting. 22. Plant according to claim 21 characterized by the fact that the collection tank comprises at least one outlet for the heavier substance collected, said outlet being located at the bottom of the tank and by the fact that the unit further comprises at least one conductivity sensor / electrical resistivity of the fluid at the outlet capable of generating a corresponding signal and means for selectively closing the output as a function of the signal detected by the sensor. 23. Method for removing at least one pollutant from a gas phase fluid flow comprising the following steps: - generating a flow of fluid in the gaseous phase (3) containing at least one polluting substance by means of at least one device (8); - forcing the passage of said flow through a thermal jump device (4) maintained at a temperature lower than that of the gas phase flow (3) to generate a ΔΤ; - condense and / or freeze at least part of the humidity and / or the polluting agent during the passage; - separating drops / micro-drops from flow in the gaseous phase (3) by using at least one droplet separator (5), said separation phase preferably being posterior to said condensation and / or freezing phase, characterized in that it further comprises a control step of the device (8) for varying the flow of fluid passing through the plant as a function of at least one control parameter of the fluid itself. Method according to claim 23, wherein the control phase of the device (8) comprises a sub-phase of varying an operating parameter of at least one fan of the device (8) and preferably a sub-phase of varying the drive torque of said fan. A method according to claim 23, wherein said control parameter is a temperature of the flowing fluid. Method according to claim 24, wherein the control step of the device (8) comprises a first drive of the fan when the system is started and a subsequent increase in the drive torque of the fan as the fluid control parameter varies. Method according to claim 26, wherein said increase in the driving torque varies continuously over time from the actuation of the device until a steady state condition is reached in which said control parameter remains substantially stationary. Method according to claim 23, characterized in that it further comprises the step of humidifying said fluid flow in the gaseous phase (3) by means of a flow humidifier (7) selectively designed to transfer, preferably by coalescence, a certain substance in the gas phase flow (3) passing through. 29. Method according to claim 28, characterized in that the humidification step precedes the condensation and / or freezing step. 30. Method according to claim 28, characterized in that the flow of fluid in the gaseous phase 3 passes in sequence at least two modules consisting of a flow humidifier (7), a thermal jump device (4) and a droplet separator ( 5), said flow preferably passing through at least three of said modules. 31. Method according to claim 23, characterized by the fact that it includes the further step of heating the flow leaving the system and the step of reusing the heated flow to dry artifacts or closed environments. 32. Method according to claim 23, characterized in that it further comprises the step of reusing the heat generated by refrigeration means (9) designed to maintain the low temperature of the thermal jump device (4) for heating internal environments.