The present invention relates to a portable device for producing drinking water from atmospheric moisture and in particular relates to a portable device powered by means of renewable energy sources.
During the last few years, both because of changing lifestyles in our society and because of the deterioration in the organoleptic qualities of mains water, there has been a considerable increase in the consumption of bottled mineral water. However, the massive use of this type of product has a significant environmental impact due to the problems associated with disposal of the plastic bottles and drums of the water dispensers and the pollution caused by the chain for production and distribution of bottled water as a whole.
Also known are water production plants which make use of the atmospheric moisture which is condensed in an evaporator of a refrigeration unit. The moisture is collected, filtered and sterilized and remineralized so as to obtain at the end of the process a water which is comparable to spring water. These plants may normally be divided into two categories:
These known systems are generally heavy and bulky and powered by AC power and therefore dependent on a mains power connection.
Another drawback of the aforementioned machines is the low efficiency of the refrigeration unit at a high ambient temperature.
The object of the present invention is to overcome these drawbacks by providing a device for producing drinking water from atmospheric moisture, which is small in size and independent of the electric mains supply so that it may be installed also in vehicles with living accommodation such as camper vans or caravans or also small-size boats.
A further object of the device according to the present invention is to provide a high refrigerating efficiency also at high ambient temperatures (as for example is the case when used in tropical areas or subtropical areas) without having to use larger size air condensers (referred to by the term “tropicalized”) which would make the device bulky and therefore difficult to transport.
These and other objects are achieved by a device according to the invention, the main characteristic features of which are defined by claim 1 in the accompanying claims. Further important characteristic features are also contained in the dependent claims.
The characteristic features and advantages of the device according to the invention will emerge more clearly from the following description of an embodiment thereof, provided by way of a non-limiting example with reference to the attached drawings in which:
With reference to said figures, the device D according to the invention comprises a heat exchanger or evaporator 1. The heat exchanger, according to a conventional constructional solution, is composed principally of a coil 10 inside which a refrigerant liquid flows. The latter is produced by a refrigeration unit 2 and is introduced into the coil at a given pressure by means of a regulating valve 3. In detail, the refrigerant liquid is introduced into the heat exchanger at low pressure, namely a pressure ranging, preferably but not exclusively, between 3 and 4 bar. Preferably, but not exclusively, the refrigerant liquid is an alkyl halogenide. The pressure values indicated above correspond to evaporation temperatures of the refrigerant liquid comprised between about 2 and 8 degrees centigrade.
The refrigeration unit is managed by a control unit 15 of the known type and therefore not described in detail, being shown only schematically in
The device further comprises means for introducing forced air 4 into the exchanger. In particular, these means comprise a blower 40 which forcedly conveys the air from the outside towards the heat exchanger 1 and in particular onto the coil 10. Advantageously a filter 41 is provided downstream of the blower so as to intercept any solid impurities present in the air, such as dust and/or pollutants.
In accordance with that known per se, the forced air in contact with the walls of the exchanger transfers its heat to the refrigerant liquid and this drop in temperature causes condensation of the water vapour contained in the said air. This condensed water is formed as droplets on the walls of the exchanger and is collected by falling inside a tray 5 and from here inside a tank 6. The transfer of the water from the tray to the tank may be performed by means of gravity or in a forced manner by means of a pump 60 (shown schematically in
The device also comprises first electric power supply means 8, shown schematically in
In a preferred constructional solution the first electric power supply means are powered by the energy generated by second electric energy means of the renewable type. In particular, these means comprise a solar panel 81 which is connected to the lithium-ion battery by means of a charge controller 82. The charge controller supplies the battery with the current generated by the solar panel at the desired voltage. For example, this value may be comprised between 12 and 24 volts, depending on the voltage of the battery to be powered.
In even greater detail, with particular reference to
The deviation means comprise a partition 14 which intercepts either branch of the duct so as to direct the air flow from the first insulated compartment 11 to the second compartment 12 or third compartment 13. The partition is operated depending on the external atmospheric conditions. When, in fact, the ambient temperature remains at optimum values, namely below a threshold value, the partition intercepts the duct 110 and the air which has passed through the evaporator and is therefore at a temperature lower than atmospheric temperature is directed into the third compartment where a refrigerating action on the water collection tank 6 occurs. When, instead, the ambient temperature is above this threshold value the partition is activated so as to free the duct 110 so that the cold air enters into the second compartment in order to help cool or in any case prevent overheating of the refrigeration unit and the battery. This circulation of the cold air inside the second compartment therefore assists operation of the refrigeration unit, thus increasing the energy efficiency of the device as a whole.
The threshold value is preferably comprised between 28 and 35 degrees centigrade; one value of this threshold value is preferably, but not exclusively, 30 degrees centigrade, depending on an atmospheric humidity value of between 50 and 55 percent. Optionally, with an increase in the humidity value, the threshold value may be indicated at a lower temperature.
Operation of the partition 140 is controlled by control means such a control board 15 (shown schematically in
The device according to the invention, in addition to solving the problems of the known devices described above, offers several novel advantages.
In detail, owing to the deviation means and the capacity to deviate the cold air either to the water collection tank or to the refrigeration unit, a device with a high refrigerating efficiency even at high ambient temperatures (e.g. as in tropical or subtropical areas) is obtained, without having to employ larger size (so-called “tropicalized”) air condensers.
The device is therefore compact and therefore may be easily transported and/or installed also on movable transportation means equipped with living accommodation (camper vans, caravans) or boats.
This installation versatility is also possible since the device is in fact independent of the electric mains, being powered with renewable electric energy generating means. Apart from the solar panel solution described above, the device may also be powered by other sources, such as micro wind power systems.
Moreover, as already mentioned above, the plant is particularly compact, also owing to the fact that the refrigeration unit is small in size, as is the lithium-ion battery which has a high charging level, while being low-weight.
Still with a view to transportability of the device, in the case where solar panels are used, the latter may be of the flexible laminated-plastic type. This type of panel, for the same electric power produced, weighs about an eighth of conventional photovoltaic panels and is not excessively prone to breakage. Similarly, in the case of micro wind power systems, micro wind generators with folding vanes may be chosen.
Finally, it is also necessary to mention the capability of the device to function as a dehumidifier. In fact, by collecting the external atmospheric moisture, it reduces the overall humidity level within the installation area.
The present invention has been described hitherto with reference to preferred embodiments thereof. It is to be understood that other embodiments relating to the same inventive idea may exist, all of these falling within the scope of protection of the claims which are attached below.
Number | Date | Country | Kind |
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102015000022571 | Jun 2015 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2016/053224 | 6/1/2016 | WO | 00 |