ES2362593A1 - Apparatus and predictive antivaho procedure. (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Predictive anti-fog device and procedure. The procedure, applied to prevent the deposition of mist on a first surface of an object (6), comprises: obtaining the temperature To of the first surface, the temperature Ta of the air facing the first surface and the relative humidity Ha of the air surrounding the first surface; - calculate, from the air temperature Ta and the relative humidity Ha of the air, the dew point temperature Tr of the air; - compare the dew point temperature Tr of the air with the temperature To of the first surface , and depending on said comparison, carry out or not the following actions: - decrease the local relative humidity of the air surrounding the first surface of the object (6); and- increasing the temperature of said first surface. Applicable to exterior or interior surfaces exposed to humid air where condensation must be prevented, such as surveillance camera visors or automobile windows.

Description

Apparatus and predictive anti-fogging procedure.

Field of the Invention

The presented invention is framed in the field of the air conditioning industry where it is required a specific control of condensation. Applicable to treatment of exterior or interior surfaces exposed to moist air in those that should prevent condensation before it appears; vg: viewfinders of surveillance cameras, ducts and enclosure walls with air conditioning, windows or glass in cars, etc.

Background of the invention

Air conditioning systems They encompass the set of techniques and methods for the treatment of air in terms of cooling, heating, degree of humidification, composition for human consumption, etc. The condensation is a phenomenon associated with thermodynamic conditions of impossibility of solubility of water vapor existing in the mixture of gases that make up the air.

Normally in the air there is a quantity of dissolved water vapor that is usually measured in terms of the relative humidity defined as the amount of water vapor that contains a mass of air in relation to the maximum amount of water vapor that could be dissolved in that same mass without condensation and maintaining the same temperature and pressure conditions. The relative humidity H r can be expressed in terms of the partial pressure of water vapor in the air:

one

where p H 2 O is the partial pressure of the water vapor in the air to be considered and p sat \ (H 2 O) is the partial pressure of that same humidity saturated air in the same thermodynamic conditions. Thus, the relative humidity shows us an index of 0 to 1 depending on the amount of possible water vapor that is dissolved in the air mass.

The partial pressure of water vapor in the air Atmospheric is a function of temperature. A supported formula by the WMO (World Metereological Organization, Organization World Meteorological) is:

2

where p H 2 O ( T ) is given in hectopascals or millibars, T in degrees celsius, a and b being experimentally determined constants: a = 17.62 and b = 243.12.

The dew temperature T r, at which the air is saturated with moisture, will be achieved, according to the expression (2) with a partial saturation pressure of:

3

Saturated air temperature or temperature dew point is that temperature below which the steam of water dissolved in the air begins to precipitate due to the impossibility of solubility.

Since the relative humidity relates the two partial pressure values of saturated and unsaturated steam, we can determine the dew temperature T r by simply dividing the expressions (2) and (3), clearing it from the resulting expression and relating it With temperature and relative humidity:

4

The expression (4) indicates that, knowing the temperature T of an arbitrary air mass and its relative humidity H r, it is possible to calculate the temperature T r below which that air will begin to condense the water vapor it contains. This will occur when that air is subjected to a thermal change that lowers its temperature below its dew point temperature T air < T r air, or encounters an object whose temperature is also lower than its temperature. dew temperature T object < T r \ air. If the air with a relative humidity and given temperature affects an object whose temperature is lower than its dew temperature, the object is surrounded by tiny droplets (fog), as a consequence of the local condensation that takes place between the surface of the object and the layer of air that surrounds it.

Saturated air without condensing moisture is It is at its dew temperature. If an air of these characteristics is heated, according to the expression (3), increases its partial saturation pressure, making its relative humidity decrease That is, by increasing the air temperature we can dissolve in it more water than we could dissolve than if We were at a lower temperature.

To avoid the condensation condition in a object, we will have to act so that the dew temperature lower and / or the temperature of the object rises above the temperature dew For the air spray temperature to fall, according to the expression (4), it is necessary that its relative humidity falls and / or that its temperature rise. Lowering relative humidity requires water removal dissolved in the air or heat it so that its dissolution capacity increase

Therefore, a system that avoids condensation on an object, must calculate the dew temperature of the air T r, and must act by increasing the temperature of the air T air> T air \ current, decreasing the relative humidity of the air H r < H r \ actual (extracting the dissolved water), or increasing the temperature of the object T object> T air \ current}. Any of these three changes will prevent the deposition of mist as long as the action generates a dew point temperature lower than the object temperature:

Non-condensing condition:

5

To maintain this condition you can follow two actions:

one.

Decrease the relative humidity of the air surrounding the object:

to)

Eliminating the water it has dissolved.

b)

Heating the air.

2.

Increase the temperature of object.

The most generalized procedure to eliminate surface fog uses the second action by thermal resistances attached to the object; for example: lunettes or thermal mirrors in cars or anti-fog mirrors in bathrooms. He The energy cost of the process is high and slow, since it is due supply energy to the object in its first volume (energy of losses), until the drops acquire energy on their surface Enough to vaporize. Whereas the heat of Water vaporization is 540 calories / gram, we would need in a ideal case without losses, a resistance of 2257 watts for evaporate 1 gram of water in a second. For example, the windows thermal cars provide a power of about 100 watts which means a time of 22 seconds to evaporate 1 gram of water.

The present invention solves the problems previous, providing a new anticipatory or predictive method that acts before the fog occurs, also reducing energy necessary to prevent the formation of fog, both in environment indoor as in outdoor environments.

Description of the invention

In the present invention an apparatus is presented and a predictive anti-fog procedure that is anticipated in the actuation of mechanisms that lower the dew temperature locally around surfaces exposed to exterior or interior environments in which condensation should be avoided, based on knowledge of the dew temperature of the air and the temperature of the object and acting through two actions: the decrease in humidity relative air surrounding the object and rising temperature of the surface of the same (not of the volume).

In outdoor environments where it is intended to avoid morning dew on surfaces such as camera viewers, optical systems (e.g. optical transceivers) or surfaces outside, a humidity reduction procedure is proposed relative relative that surrounds the object generating an air cavity convective hot. Convective hot air decreases the local relative humidity and increases the surface temperature of the surrounding area

In indoor environments where moisture relative air is very variable, such as housing or cars, a procedure for reducing the local relative humidity from a forced laminar stream of hot dry air over the surface in question: walls, windows or windows. An actuator is used for this. based on a heat pump.

The predictive anti-fogging device consists of a electronic circuit that contains a microcontroller that receives information of two temperature sensors and a humidity sensor and runs an anticipation algorithm that drives an actuator decreasing the surrounding relative humidity and increasing the temperature of a surface where the condensation.

A temperature sensor and a humidity sensor placed outside the influence of the actuator. Other sensor temperature is located on the surface of the object where it should Avoid condensation.

From the measurement of the temperature and relative humidity of the surrounding air ( T a, H a), the microcontroller calculates the dew temperature T r, according to the expression (4) at regular intervals time t _ {m}. It then measures the temperature of the object T o and compares it with the dew temperature of the air T r. If the temperature of the object is maintained above the dew temperature with a safety margin δ T , fog will not be deposited on the object (condition expressed in inequality (5)). In the case where the dew point temperature rises in violation of the safety margin but not the condition (5), the microcontroller starts the actuator that decreases the relative humidity of the surrounding air and increases the temperature of the object. The safety margin δ T guarantees non-deposition of fog and anticipation in the decision to change the environmental conditions. This situation is maintained as long as the dew point temperature does not fall below a value below the object temperature plus the safety margin T r < T o + δ T. This algorithm is fully described in the detailed description.

There are two types of actuators that they perform the same function consisting of decreasing humidity surrounding relative and increase the object temperature for two types of environments: exterior and interior.

The outdoor anti-fog actuator consists of a cavity where the object is located where the condensation and a unidirectional heating sheet that generates a hot air convection current. It is presented in this invention an embodiment of the actuator for camera viewers of surveillance and optical systems for outdoor use.

The indoor anti-fog actuator consists of a turbine that injects moist air into the cold focus of a pump of heat generating a cooling and condensation process transforming moist air into cold and dry air. Later, this air is processed in the hot spot of the pump to raise its temperature generating a laminar stream of dry air hot that is directed towards the object where the condensation. An embodiment of the actuator for windshields and windows of a car. Thus proposes to process the laminar flow of air generated by a thin duct with blades and a wing arranged so that they create uniform laminar current over the large area of a window.

In both cases it is demonstrated analytically through fluid dynamics simulation that the actuators presented cause a decrease in relative humidity surrounding and an increase in temperature of the object.

Brief description of the drawings

Then it goes on to describe very brief a series of drawings that help to better understand the invention and that expressly relate to an embodiment of said invention presented as a non-limiting example of is.

Figure 1 shows the functional diagram of Predictive anti-fogging device blocks.

Figures 2A and 2B show the diagrams schematic of the predictive anti-fogging device actuator for outdoor and indoor environments, respectively.

Figures 3A and 3B show an embodiment of the outdoor anti-fogging device in a viewfinder of an optical system and an exploded view of the unidirectional heating sheet of the actuator

Figures 4A, 4B, 4C and 4D show the dynamics convective hot air and thermal properties of the viewfinder of an outdoor optical system: flow lines and speeds, Map of isotherms, relative humidity and mass fraction.

Figure 5 shows the arrangement of elements in an embodiment of the indoor anti-fogging apparatus in a car window.

Figures 6A, 6B and 6C show the apparatus interior anti-fog in a car window with details of the conductors of the flow, director wing and elements of the indoor actuator

Figures 7A, 7B and 7C show the results of the production of dry hot air by the actuator indoor anti-fog: temperature distribution, change of relative humidity and mass fraction of condensed water.

Figures 8A, 8B and 8C show the dynamics of the laminar flow of the generated air and the thermal properties of the window inside a car: speeds, map of Isotherms and relative humidity.

Figure 9 shows the flow chart of Antifog prediction or anticipation algorithm data.

Figure 10 shows the functional diagram of blocks of the predictive anti-fogging device applied together to indoor and outdoor environments.

Detailed description of the invention

In this invention an apparatus and a predictive anti-fog procedure that is anticipated in the performance of mechanisms that lower dew point temperature around surfaces exposed to exterior and / or interior environments in that condensation should be avoided.

The functional block diagram of the device Predictive anti-fog is shown in Figure 1. This consists of a 1 relative humidity sensor, a temperature sensor air 2 and a temperature sensor 3 of object 6 to avoid fog deposition The sensors (1, 2, 3) are read by a microcontroller 5 which, after executing the anticipation algorithm or prediction, activated by drivers to an actuator 4 that modifies the properties of the surrounding air lowering its relative humidity and point of dew and increasing the temperature of the object.

The actuator 4 that modifies the properties of the surrounding air depends on the confinement characteristics of the air to be processed. Figures 2A and 2B show the diagrams actuator 4 schematics for outdoor and indoor environments, respectively. For outdoor environments, actuator 4 consists of a cavity 7 where the object 6 is placed to avoid the deposition of mist. Cavity 7 creates a local confinement of the air. The air confined is heated by a heating sheet unidirectional 8 that is inside the cavity 7 forming a angle less than 45 degrees with the vertical. Optimal inclination allows maximum thermal exchange between the heating sheet and the air, and depends on the size and power of the heating sheet used (the width of the sheet and its temperature), normally between 30 and 45 degrees. The temperature of the heating sheet Unidirectional should be relatively high to facilitate the heat exchange with cold air (v. g. more than 70 ° and less than 100º Celsius to avoid phase changes). So, the air that touches the hot surface, heats up and decreases its density causing a convection current inside the cavity 7. Al After a few seconds the air containing cavity 7 has increased its temperature (decreasing its relative humidity), at once you have heated the surface of object 6 to avoid fog deposition

For indoor environments, the actuator consists of a heat pump 12 that generates a cold bulb 10 and a hot bulb 11 where there are two heat exchangers (13, 13 '). The humid air inside is collected by a turbine 9 which leads to the heat exchanger 13 of the cold bulb 10 of the heat pump 12. The temperature of the cold bulb must be below the dew temperature of the processed air so that it it will condense the water 31 it contains in condenser 14. The dew temperature of the processed air will be equal to the temperature of the cold focus of the heat pump. The dry cold air produced is led to heat exchanger 13 'of hot spot generating a hot dry air with a very low relative humidity. Hot dry air is directed through a duct with blades flow directors towards the object to avoid the deposition of fog 6 '.

Figures 3A and 3B show an embodiment of the outdoor anti-fogging device in a viewfinder of an optical system, for example a laser optical transceiver, along with a view exploded unidirectional heater sheet 8 of the actuator 4. The optical system box has been made by generating a cavity 7 around the glass viewfinder, which is object 6 where it should be Avoid the deposition of mist. The box 21 and the lid 22 that generate the cavity (creating a kind of visor) and wrap the visor of Glass have been made in aluminum. To minimize transmission of heat by conduction between aluminum and glass has sandwiched between them a crown 20 of an insulating material of the heat, for example polycarbonate. The heating sheet 8, located at a small distance (for example, about 5 mm) from the lid 22 and with an angle of about 30º with respect to this one, generates unidirectional heat on the metal surface 23 made in aluminum or copper on which an electrical resistance adheres in zigzag 24 covering its entire surface. The back of the electrical resistance 24 is attached to a thermal insulating sheet 25 (in a preferred embodiment of polypropylene) with a coating of aluminum to reflect the heat generated by radiation towards the surface 23. Polycarbonate backsheet 26 and the 27-27 'brackets complete the structure of the unidirectional heating sheet 8 of the actuator 4.

In the presented embodiment of the apparatus outdoor anti-fog, the temperature of the heating sheet Unidirectional is around 80ºC. In a simulated environment of a static air at 12ºC and 70% humidity (dew temperature 6.7 ° C), assumed the initial temperature of the box and display of 5 ° C; that is, by checking the condition of vapor deposition, the simulator calculates the stationary response (thermodynamics of equilibrium), showing the following results (Figures 4A, 4B, 4C and 4D):

one.

The unidirectional heating sheet 8, heated to 80 ° C, generates a forced convective air flow with maximum speeds of 0.3 m / s in a section of about 5 mm passing between the sheet and the lid laminating the viewfinder (Figure 4A).

2.

In few seconds, all the air inside the cavity is found at an average temperature of 18 ° C. The viewfinder, initially at 5 ° C heats by presenting a map of isotherms with temperatures of the order 10 ° C above the initial temperature (Figure 4B).

3.

The relative air humidity on the surface of the viewfinder low order 30 percentage points versus initial relative humidity existing. So the dew point temperature drops to 4.1ºC (18ºC - 40%) (Figure 4C).

Four.

With the viewfinder at 18º and with an air at 40% average relative humidity is impossible the deposition of fog as shown by the map of mass fraction of condensed water on the viewfinder surface (Figure 4D).

Figure 5 shows another embodiment of the apparatus predictive anti-fog, in this case for indoor, in a 70 cm car window, this embodiment being applicable also to the windshield of the vehicle. In Figures 6A, 6B and 6C, show details of actuator 4 from different views. In the Figure 6A schematically shows the location of the 1 relative humidity sensor, temperature sensor air 2 and temperature sensor 3 of object 6 to avoid deposition of fog These sensors are connected to the microcontroller 5. The object 6 to avoid the deposition of mist corresponds to the interior surface of the window glass. Air flow dry must adapt to the shape of object 6 in which it should be avoided condensation The actuator 4 through the nozzle 19 (shown in Figure 6C) is connected to a vane duct 15 constructed in ABS and formed by 140 blades 5x5 mm wide (Figure 6A), which they are distributed at the base of the window along wing 16 which redirects the flow to it in a section 2.5 mm wide by 70 cm long (figure 6B). Thus, the air injected by the turbine 9 is distributed in a laminar and uniform manner over the entire window surface. Details of actuator 4 are shown in figure 6C. Heat pump 12 is made with cells peltier connecting its hot 10 and 11 hot spot with the heat exchangers 13 and 13 'respectively. The heat exchangers made with aluminum foil parallel to the flow, they are placed in a "U" shaped conduit 18 made of polypropylene or pressed rock wool with reinforcement aluminum exterior and interior forming an adiabatic cavity at whose base is the capacitor 14 that collects by gravity the condensed water through the drain pipe 17. The inlet of the duct 18 is connected to turbine 9 and the outlet of said duct 18 connects to the nozzle 19 that adapts the air outlet to the vane duct 15.

The formation of hot dry air by the indoor anti-fog actuator 4 is shown with an example of simulation in which a humid air environment of 15ºC and 70% relative humidity (dew point temperature of 9.6ºC). This air is injected by turbine 9 with a flow of 0.8 m 3 / min heading towards the cold focus 10-13 of the pump heat that is at a temperature of 5 ° C. After his condensation in condenser 14, is heated to 70 ° C in the focus hot pump 11-13 'heading towards the exit nozzle 19. After calculating the stationary response (equilibrium thermodynamics), the results are the following:

one.

He moist air at 15 ° C flows in a laminar regime at an average speed of 17 m / s per "U" tube 18 presenting a distribution thermal as shown in the section of Figure 7A. The average temperature of exit is of the order of 35ºC.

2.

TO as the air temperature changes between 5ºC of the focus cold and 70ºC of the hot spot its relative humidity changes from 70% of its initial value at an average value of less than 20% in the output (Figure 7B).

3.

To the go through the cold spot the temperature of the humid air is located by below its dew temperature and condenses as water. The Figure 7C illustrates the distribution of the water mass fraction condensed showing the deposition of water in condenser 14 and its drain outlet 17.

The hot dry air produced in the actuator 4 it is injected into the vane duct 15 to be directed towards the window supposed to an initial temperature of 5ºC, temperature below the dew temperature. Figure 8A shows the flow distribution and speeds over the window. In this realization, the average speed of exit is of 5 m / s being demonstrated the ability of the set of blades presented to produce a laminar regime throughout its length being the thickness laminar about 2.5 mm. The average relative humidity of this sheet is less than 40% since, in steady state, dry air at 35ºC and 20% humidity produced by the actuator 4, mixes with the air environmental of that surface area with a humidity of 70%. Whereas the window is in full volume at a initial temperature of 5ºC, in steady state there is a air sheet that heats the surface of the window to a average temperature of 17ºC and 40% humidity with the distribution thermal pattern shown in Figure 8B (margins between 15ºC and 21ºC). In these conditions, the stationary laminar air around the Ventanilla has an average dew point temperature of less than 3.3ºC, lower temperature than the surface of the window, so There will be no fog. Figure 8C shows the distribution of the relative humidity in the window. At the base of the window the relative humidity is less than 35% while in the contours outside is less than 55% with a temperature higher than 15 ° C Considering this worst case, the dew point temperature is 6 ° C, temperature well below surface temperature of the window.

The prediction or anticipation algorithm Detailed anti-fog executed by microcontroller 5 is described to continued showing its data flow diagram in Figure 9.

The measurement and calculation variables is performed by the microcontroller at regular intervals t _ {m} seconds. These intervals verify the Nyquist theorem and are calculated based on a study of the evolution of the relative temperatures and humidity that occur in the environment where the predictive anti-fogging apparatus is located (intervals between a few seconds and several minutes).

Description of variables and parameters

-

Measurement period: t _ {m}

-

Binary actuator activation variable: A

-

Relative humidity of the air: H a

-

Air temperature: T a

-

Object temperature: T o

-

Dew Temperature: T r

-

Constant value parameter representing the safety margin expressed in degrees Celsius: δ T.

According to the flowchart of Figure 9 the procedure is repeated every t _ {m} seconds and may be t _ {m} a predetermined or variable or constant in time value is:

S0. Initialization of variables:

-

Set the parameter of the safety thermal margin δ T

-

Pin up the variables to an initial value.

S1. Data acquisition:

-

Acquire the value of the air temperature: T a

-

Acquire the value of the relative humidity of the air: H a

-

Acquire the temperature value of the object: T 0.

S2 Dew temperature calculation according to expression (4):

-

Calculate dew temperature: T r

S3 Comparison of dew temperature more The safety margin with the object temperature:

-

If T o ≥ T r + δ T , deactivate actuator A = 0 and return to S1.

-

If T 0 < T r + δ T , activate actuator A = 1 and return to S1.

The conditions to verify to activate and / or deactivating the actuator may be different ones, as per example:

-

If T o <2 • T r, activate actuator A = 1 and return to S1.

-

The deactivation ( A = 0) could be manual, and not automatic, or with other different conditions and / or safety margins.

Likewise, the present invention could be Use together for indoor and outdoor environments, such as shown in Figure 10, for example to avoid deposition of fog outside and inside systems in which it is impossible to completely remove moisture (glazing in homes, shop windows, skylights, glass enclosures in pools, etc ...). In this case you could use a single microcontroller (5), or two different ones, to measure the different temperature sensors (1, 1 ', 3, 3') and humidity (2, 2 ') of both environments (exterior and interior) and to control the corresponding actuators (4, 4 '), exterior and interior, according to He has explained above.

Claims (18)

1. Predictive anti-fogging apparatus, characterized in that it comprises: - first temperature sensing means (3), responsible for measuring the temperature T o of a first surface of the object (6) to prevent the deposition of mist; - first actuator means (4) configured, when activated, to:

?

decrease relative humidity local air surrounding the first surface of the object (6); Y

?

increase the temperature of said first surface;

- second temperature sensing means (2), responsible for measuring the temperature T a of the air facing the first surface and outside the influence of the first actuating means (4); - first air relative humidity sensing means (1), responsible for measuring the relative humidity H a of the air facing the first surface and outside the influence of the first actuating means (4); - control means (5) configured to time to time t _ {m}:

?

obtain from the first temperature sensing means (3), second temperature sensing means (2) and first sensing means of relative air humidity (1), the temperature T o of the first surface, the temperature T a of the air and the relative humidity H a of the air;

?

calculate, from the temperature T a of the air and the relative humidity H a of the air, the temperature T r of the air dew;

?

compare the dew temperature T r of the air with the temperature T o of the first surface, and activate or not the first actuator means (4) according to said comparison.

2. Predictive anti-fogging device according to claim 1, wherein the control means (5) are additionally configured for, once the comparison of the air dew point T r with the temperature T o of the first surface, deactivate or not the first actuator means (4) depending on said comparison. 3. Predictive anti-fogging device according to any of the preceding claims, wherein the control means (5) are configured to activate the first actuator means (4) If the following condition is met: 6 where δ T is a safety thermal margin of predetermined value. 4. Predictive anti-fogging device according to any of the preceding claims, wherein the first means temperature sensors (3) comprise a temperature sensor adhered to the surface on which the condensation. 5. Predictive anti-fogging device according to any of the preceding claims, where to decrease the humidity local relative of the surrounding air to the first surface of the object (6) the first actuator means (4) are configured to perform at least one of the following actions:

-

remove the water that has dissolved the surrounding air;

-

heat the surrounding air.

6. Predictive anti-fogging device according to any of the preceding claims, wherein the control means (5) They comprise a microcontroller. 7. Predictive anti-fogging device according to any of claims 1 to 6, wherein the first actuator means (4) include: - a cavity (7) in charge of confining locally the air surrounding the first surface of the object (6); - a unidirectional heating sheet (8) placed at an angle to the first surface and configured, when the first actuator means (4) are activated, for, by generating unidirectional heat in its surface closest to the first surface of the object (6), create in the air locally confined in the cavity (7) a hot air convection current on the first surface of the object (6). 8. Predictive anti-fogging apparatus according to claim 7, wherein the unidirectional heating sheet (8) comprises
from: - a metal surface (23), which corresponds to the surface of the unidirectional heating sheet (8) more close to the first surface of the object (6); - an electrical resistor (24) that covers the back of said metal surface (23); - a thermal insulating sheet (25) attached to the back of the electric heater (24) with a metal coating to reflect heat generated by radiation towards the metal surface (23). 9. Predictive anti-fogging device according to anyone of claims 7 to 8, the actuator means being configured, when activated, to heat the sheet unidirectional heater (8) at a high temperature below of boiling water. 10. Predictive anti-fogging device according to any of claims 7 to 9, wherein the heating sheet unidirectional (8) forms an angle, with respect to the first surface, less than 45ºC. 11. Predictive anti-fogging device according to any of claims 1 to 6, wherein the first actuator means (4) include: - a heat pump (12) in whose cold spotlights (10) and hot (11) heat exchangers (13, 13 '); - a conduit (18) containing the heat exchangers (13,13 '); - a condenser (14) connected to the conduit (18); - a turbine (9) in charge, when the first actuator means (4) are activated, of injecting air through the duct (18); the conduit (18) being configured to: conduct the air injected by the turbine (9) towards the cold bulb (10) of the heat pump (12) to generate the condensation of the water contained in the condenser (14), obtaining cold and dry air; Conduct the cold and dry air through the hot spot (13 '), producing a dry and hot air; direct the hot dry air towards the first surface of the object (6). 12. Predictive anti-fogging device according to claim 11, wherein the conduit (18) is "U" shaped and the condenser (14) and a drain (17) are arranged at its base. 13. Predictive anti-fogging device according to any of claims 11 to 12, comprising a vane duct (15) with a plurality of blades distributed at the base of the first surface of the object (6) along a wing (16), being said vane duct (15) responsible for directing the dry air and hot from the duct (18) directly and evenly over said first surface of the object (6). 14. Predictive anti-fogging device according to any of claims 11 to 13, wherein the heat pump (12) It comprises peltier cells. 15. Predictive anti-fogging device according to any of the preceding claims, comprising further: - third temperature sensing means (3 '), responsible for measuring the temperature T o' of a second surface of the object (6), opposite the first surface; - second actuator means (4 ') configured, when activated, to:

?

decrease relative humidity local air surrounding the second surface of the object (6); Y

?

increase the temperature of said second surface;

- fourth temperature sensing means (2 '), responsible for measuring the temperature T a' of the air facing the second surface and outside the influence of the second actuating means (4 '); - second means of relative humidity of the air (1 '), responsible for measuring the relative humidity H a' of the air facing the second surface and outside the influence of the second actuating means (4 '); where the control means (5) are additionally configured for, from time to time:

?

obtain from the third temperature sensing means (3 '), fourth temperature sensing means (2') and second air relative humidity sensing means (1 '), the temperature T o' of the second surface, the temperature T a 'of the air and the relative humidity H a' of the air;

?

calculate, from the temperature T a 'of the air and the relative humidity H a' of the air, the temperature T r 'of air dew;

?

compare the air dew point T r 'with the temperature T o' of the second surface, and activate or not the second actuator means (4) according to said comparison.

16. Optical transceiver comprising: - a glass sight glass (6), through which receives and transmits the optical information, being the object to avoid fog deposition; - the anti-fogging device according to any of the claims 7 to 10, wherein the cavity (7) is formed by a housing (21, 22) that surrounds the glass sight glass (6) as a visor. 17. Optical transceiver according to claim 16, which comprises a crown (20) of a heat insulating material, surrounding the glass sight glass (6) to minimize the transmission of the heat by conduction between the housing (21, 22) and the glass sight glass (6). 18. demister predictive method applied to prevent vapor deposition on a first surface of an object (6), characterized by comprising performing at certain time t {m} the following steps: - obtaining the temperature T o of the first surface, the temperature T a of the air facing the first surface and the relative humidity H a of the air surrounding the first surface; - calculating, from the temperature T a of the air and the relative humidity H a of the air, the temperature T r of the air dew; - compare the T {r} air dew point temperature with the temperature T {or} of the first surface, and a function of said comparison performed or not the following:

?

decrease relative humidity local air surrounding the first surface of the object (6); Y

?

increase the temperature of said first surface.