ITMI20121686A1 - COOLING TOWER, PARTICULARLY OF A CLOSED CIRCUIT TYPE. - Google Patents

Description

"COOLING TOWER, PARTICULARLY OF THE CLOSED CIRCUIT TYPE"

DESCRIPTION

The present invention relates to a cooling tower, particularly of the closed circuit type.

As is known, cooling towers are used for cooling refrigerant liquids suitable for cooling particular users.

More precisely, the refrigerant liquid is cooled by means of a heat exchanger, generally made of a tube bundle, housed inside the cooling tower, where it is hit by a flow of forced air taken from the external environment.

According to the characteristics of the air, that is, according to its temperature and the temperature to be obtained inside the tube bundle, the use of two types of tube heat exchanger is known.

In the event that the air has a higher temperature, which occurs in the summer climatic seasons, it is preferable to use smooth pipes as, precisely in these conditions, they offer the highest heat exchange yields.

The subtraction of heat from the internal liquid occurs by evaporation by wetting the smooth tube exchanger caused, in countercurrent, by a flow of air drawn from the outside.

On the other hand, in the case in which the air has a lower temperature, which occurs in the winter climatic seasons, it is preferable to use finned tubes as, precisely in these conditions, they offer the highest heat exchange yields.

In order to create a cooling tower suitable for operating in any climatic condition, evaporators have been developed that allow the air temperature to be lowered, allowing the use of finned tube heat exchangers even in the hottest and humid months. .

This solution, which obviously leads to an increase in both operating costs and construction costs of the cooling tower, is however not sufficient to keep the efficiency of the cooling tower high.

The main aim of the present invention is to provide a cooling tower, particularly of the closed circuit type, which is suitable for its use both in the summer and winter climatic seasons, without suffering drops in the efficiency of the heat exchanger (s) used. .

Within this aim, an object of the present invention is to provide a cooling tower with a simple architecture and, therefore, with low costs, as well as, thanks to its particular construction characteristics, which is able to give the most ample guarantees of reliability and safety in use.

Not least object of the present invention is to provide a cooling tower which can be easily obtained starting from elements and materials commonly available on the market and which, moreover, is competitive from a purely economic point of view with respect to the known art. The aforementioned task, as well as the aforementioned purposes and others which will appear better later, are achieved by a cooling tower, particularly of the closed circuit type, comprising a hollow body equipped with at least a first air intake, at least one second air intake and at least one main opening in such a way as to define a first air passage circuit and a second air passage circuit delimited by the internal walls of said hollow body and extending, respectively, between said at least one first air intake and said at least one main opening and between said at least one second air intake and said at least main opening, along said air passage circuits being housed, respectively, at least one first heat exchanger and at least one second exchanger of heat traversed by a fluid to be cooled and capable of releasing heat, respectively, to a first flow of air and to a second flow of air converging in de said air passage circuits, in correspondence with said at least one main opening, fan means being provided for generating said air flows, characterized in that they comprise first closing means for said at least one first air intake and second means for closing said at least one second air intake which can be selectively activated for the interruption of at least one of said air flows.

Further characteristics and advantages will become clearer from the description of a preferred but not exclusive embodiment of a cooling tower, particularly of the closed circuit type, illustrated by way of non-limiting example, with the aid of the accompanying drawings, in which :

Figure 1 is a front elevation view of the cooling tower according to the present invention;

Figure 2 is a side elevation view of the cooling tower shown in Figure 1;

Figures 3 and 4 are two schematic side elevation views of the cooling tower shown in the previous figures, according to two operating modes.

With reference to the aforementioned figures, the cooling tower, particularly of the closed-circuit type, globally indicated with the reference number 1, comprises a hollow body 2 made for example of a box-like body having a substantially longitudinal development along a preferred direction and equipped with at least one first air intake 3, at least one second air intake 4 and at least one main opening 5 in such a way as to define a first air passage circuit and a second air passage circuit delimited by the internal walls of the hollow body 2 and developing, respectively, between the first air intake 3 and the main opening 5 and between the second air intake 4 and the main opening 5.

More specifically, the hollow body 2 comprises a first end portion 2a defining the support base of the cooling tower 1 and, in correspondence with its side walls, a plurality of first air intakes 3 and a second end portion 2b defining, at its side walls and at its upper base, respectively a plurality of second air intakes 4 and two main openings 5.

Along the previously defined air passage circuits, at least one first heat exchanger 6 and at least one second heat exchanger 7 are suitably housed, respectively, through which a fluid to be cooled and capable of releasing heat, respectively, to a first flow of heat. air 8 and to a second flow of air 9 confluent in the air passage circuits.

In the particular embodiment proposed, the first heat exchanger 6, schematically represented in the aforementioned figures by a dashed rectangle, is housed in the first end portion 2a and comprises a battery of smooth tube bundles suitable for transferring heat to the first flow of air 8 during the humid climatic season.

As regards the second heat exchanger 7, this is housed in the second end portion 2b and comprises a battery of finned tube bundles suitable for transferring heat to the second air flow 9 during the dry climatic season.

Advantageously, this second heat exchanger 7 has a substantially toroidal conformation in such a way as not to intercept the first flow of air 6, crossing it centrally and being totally bypassed.

According to the invention, first closing means 12 of the first air inlets 3 and second closing means 13 of the second air intakes 4 are provided, which can be activated selectively for the interruption of at least one of the two air flows 8 and 9.

Advantageously, the closing means 12 and 13 are of the type with automatic activation and deactivation as a function of the pressure difference between the internal environment of the hollow body 2 and the external environment of the hollow body 2.

The pressure difference mentioned above is made possible thanks to the presence, in correspondence with the main openings 5, of fan means 14 suitable for generating the air flows 8 and 9.

More specifically, these fan means 14, which comprise at least one axial fan 15 for each main opening 5 associated externally with the hollow body 2 in correspondence with the relative main opening 5, are of the two-way operating type in such a way that, corresponding to a their first mode of operation, the first air flow 8 is generated by the intake of air through the first air intakes 3 and which flows out of the hollow body 2 through the main openings 5 investing only the first heat exchanger 6 and in such a way that, corresponding to a second mode of operation of the fan means 14, the second flow of air 9 is generated by the intake of air through the main openings 5 and that flows out of the hollow body 2 through the second inlets air 4 investing only the second heat exchanger 7.

In this way, as shown in Figures 3 and 4, the first closing means 12 can be activated as a result of an increase in pressure inside the hollow body 2 with respect to the pressure value of the external environment and can be deactivated as a result of a pressure decrease inside the hollow body 2 with respect to the pressure value of the external environment.

In the same way, the second closing means 13 can be activated by effect of a lowering of pressure inside the hollow body 2 with respect to the pressure value of the external environment and can be deactivated by effect of an increase in pressure inside the body. cable 2 with respect to the pressure value of the external environment.

Advantageously, the closing means 12 and 13 comprise shutters 16 and 17, respectively, lower and upper, normally closed due to the effect of the earth's gravitational field.

In this way, in the absence of pressure differences between the internal environment of the hollow body 2 and the external environment of the same, the shutters 16 and 17 remain closed due to their weight.

The cooling tower 1 is therefore able to operate with both types of heat exchangers, making the most of their respective performance characteristics and directing the refrigerant fluid to be cooled, through an electronically controlled system, for example by means of a PLC (Programmable Logic Controller ), in the exchanger which is considered to have the best performance at that moment.

In fact, the two heat exchangers 6 and 7 are selectively fed by a single hydraulic system 18 in such a way as to feed the first heat exchanger 6 in the case of generation of the first air flow 8 and in such a way as to feed the second heat exchanger. heat 7 in the case of generation of the second flow of air 9.

The "switch" temperature from wet to dry operation and vice versa can be changed at will in the operating range of the cooling tower 1 in the two conditions.

In more detail, as shown in Figure 3, in air conditions with a high water content, i.e. in humid climatic seasons, only the first heat exchanger 6 is powered and the axial fans 15 operate in such a way as to suck air from inside the hollow body 2 decreasing its internal pressure with respect to the external environment.

This lowering of pressure consequently leads to the opening of the lower shutters 16 and to the closure of the upper shutters 17 with the formation of the first flow of air 8 which exclusively affects the first heat exchanger 6 so as to cool the fluid circulating therein.

Similarly, as shown in Figure 4, in the conditions of air with low water content, i.e. in dry climatic seasons, only the second heat exchanger 7 is fed and the axial fans 15 operate in the opposite way to that described above, so as to blow air inside the hollow body 2 increasing its internal pressure with respect to the external environment.

This increase in pressure consequently leads to the closing of the lower shutters 16 and to the opening of the upper shutters 17 with the formation of the second flow of air 9 which exclusively affects the second heat exchanger 7 so as to cool the fluid circulating therein.

In practice it has been found that the cooling tower, particularly for the closed circuit type, overcomes the drawbacks of the known art, being able to operate extremely efficiently and at high efficiency with any degree of air humidity.

In more detail, thanks to the construction characteristics of the cooling tower according to the invention, it is possible to make the most of your types of heat exchangers with which it is equipped, i.e. those with smooth tubes and those with finned tubes, in the conditions in which they work. better: evaporative in summer (hot and drier climate, reference parameter the wet bulb temperature) use of smooth tubes, air in winter (cold and wetter climate, reference parameter the dry bulb temperature) use of finned tubes to greater surface.

The invention thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept.

Furthermore, all the details can be replaced by other technically equivalent elements.

In practice, the materials employed, so long as compatible with the specific use, as well as the contingent shapes and dimensions, may be any according to requirements.

Claims (10)

R IV E N D I C A Z I O N I 1. Cooling tower (1), particularly of the closed circuit type, comprising a hollow body (2) equipped with at least one first air intake (3), at least one second air intake (4) and at least a main opening (5) in such a way as to define a first air passage circuit and a second air passage circuit delimited by the internal walls of said hollow body (2) and extending, respectively, between said at least one first intake d air (3) and said at least one main opening (5) and between said at least one second air intake (4) and said at least main opening (5), along said air passage circuits being housed, respectively, at least a first heat exchanger (6) and at least a second heat exchanger (7) traversed by a fluid to be cooled and capable of releasing heat, respectively, to a first flow of air (8) and to a second flow of air (9 ) converging in said air passage circuits, in correspondence with said al minus a main opening (5), ventilator means (14) being provided for generating said air flows (8, 9), characterized in that it comprises first closing means (12) of said at least one first intake air (3) and second closing means (13) of said at least one second air intake (4) which can be selectively activated for the interruption of at least one of said air flows (8, 9). 2. Cooling tower (1), according to the preceding claim, characterized in that said closing means (12, 13) are of the type with automatic activation and deactivation according to the pressure difference between the internal environment of said hollow body (2) and the external environment of said hollow body (2). 3. Cooling tower (1), according to claims 1 or 2, characterized in that said fan means (14) are of the two-way operating type in such a way that, corresponding to their first operating mode, said first air flow (8) is generated by the intake of air through said at least one first air intake (3) and which flows out of said hollow body (2) through said at least one main opening (5) investing said at least a first heat exchanger (6) and in such a way that, corresponding to a second operating mode of said fan means, said second air flow (9) is generated by the intake of air through said at least one main opening ( 5) and which flows out of said hollow body (2) through said at least one second air inlet (4) hitting said at least one second heat exchanger (7), said first closing means (12) being activated to effect d i an increase in pressure inside said hollow body (2) with respect to the pressure value of said external environment and being deactivated by effect of a pressure decrease inside said hollow body (2) with respect to the pressure value of said external environment, said second closing means (13) being activated by effect of a lowering of pressure inside said hollow body (2) with respect to the pressure value of said external environment and being deactivated by effect of an increase in pressure inside said hollow body (2) with respect to the pressure value of said external environment. 4. Cooling tower (1), according to one or more of the preceding claims, characterized in that said closing means (12, 13) comprise dampers (16, 17) normally closed due to the effect of the earth's gravitational field. 5. Cooling tower (1), according to one or more of the preceding claims, characterized in that said heat exchangers (6, 7) are selectively fed by a single hydraulic system (18) in such a way as to feed said at least one first heat exchanger (6) in the case of generation of said first air flow (8) and in such a way as to feed said at least one second heat exchanger (7) in the case of generation of said second air flow (9). 6. Cooling tower (1), according to one or more of the preceding claims, characterized in that said hollow body (2) has a longitudinal development according to a preferred direction and comprises a first end portion (2a) defining, in correspondence of its side walls, a plurality of first air intakes (3) and a second end portion (2b) defining, at its side walls and at its upper base, respectively, a plurality of second air intakes air (4) and said at least one main opening (5), said at least one first heat exchanger (6) being housed in said first end portion (2a) and said at least one second heat exchanger (7) being housed in said second end portion (2b). 7. Cooling tower (1), according to one or more of the preceding claims, characterized in that said at least one second heat exchanger (7) has a substantially toroidal conformation so as not to intercept said first air flow (8) . 8. Cooling tower (1), according to one or more of the preceding claims, characterized in that said fan means (14) comprise at least one axial fan (15) associated externally to said hollow body (2) in correspondence with said at least one main opening (5). 9. Cooling tower (1), according to one or more of the preceding claims, characterized in that said at least one first heat exchanger (6) comprises a battery of smooth tube bundles adapted to transfer heat to said first air flow (8 ) during the humid climatic season. 10. Cooling tower (1), according to one or more of the preceding claims, characterized in that said at least one second heat exchanger (7) comprises a battery of finned tube bundles adapted to transfer heat to said second air flow (9) ) during the dry climatic season.