CROSS-REFERENCE TO RELATED APPLICATIONS

This Patent Application claims priority from Italian Patent Application No . 102022000016014 filed on July 28 , 2022 , and US Patent Application No . 17 / 876 , 216 filed on July 28 , 2022 , the entire disclosure of which is incorporated herein by reference .

TECHNICAL FIELD

The present invention concerns an air conditioning unit , in particular a packaged air conditioning unit .

The present invention finds its preferred, although not exclusive , application in telecommunication and IT shelters conditioning . Reference will be made to this application by way of example below .

BACKGROUND OF THE INVENTION

Air conditioning unit , as known, perform a refrigeration cycle to cool or heat an airflow directed to an environment to be conditioned .

In case of spaces voted to house telecommunication and IT shelters , it is requested that the air conditioning units provide a cool air flow to maintain the aforementioned spaces at a predefined temperature to guarantee a good operation of the electronic elements of the telecommunication and IT shelters . To this aim it is known to provide the aforementioned air conditioning units with a so-called " free cooling" functionality, i . e . to avoid to use energy to carry out actively the refrigeration cycle and use the external air to the space to be conditioned to cool down the space itsel f .

It is clear that the aforementioned functionality is possible only when the external air is cooler than the air in the space to be conditioned .

However, the addition of a free-cooling functionality to known air conditioning unit needs to modi fication to the layout of the air conditioning unit that usually lead to a substantial reconfiguration of its shape and encumbrance .

Therefore , it is clear that it is needed to provide a free cooling functionality in air conditioning unit that is economic and compact .

An aim of the present invention is to satis fy the above mentioned needs in a cost-ef fective and optimi zed manner .

SUMMARY OF THE INVENTION

The aforementioned aim is reached by an air conditioning unit as claimed in the appended set of claims .

BRIEF DESCRIPTION OF DRAWINGS

For a better understanding of the present invention, a preferred embodiment is described in the following, by way of a non-limiting example , with reference to the attached drawings wherein : • Figure 1 is a schematic representation of a first embodiment of an air conditioning unit according to the invention;

• Figure 2 is a schematic representation of a second embodiment of an air conditioning unit according to the invention;

• Figures 3A-3B are schematic representation of the air conditioning unit of figures 1 and 2 in a first operative condition;

• Figures 4A-4B are schematic representation of the air conditioning unit of figures 1 and 2 in a first operative condition;

• Figures 5A-5B are schematic representation of the air conditioning unit of figures 1 and 2 in a first operative condition; and

• Figures 6A- 6B are schematic representation of the air conditioning unit of figures 1 and 2 in a first operative condition .

DETAILED DESCRIPTION OF THE INVENTION

Figures 1 and 2 discloses an air conditioning unit 1 for condition a space S delimited by a structure B provided with a first and a second opening O' , O' ' .

In both embodiment of figures 1 and 2 the structure B may be a building provided with a pair of openings O' , O' ' that are linearly, e . g . vertically, aligned one with respect to the other, i . e . the opening planes are substantial coincident .

The air conditioning unit 1 comprises a structure 2 , preferably substantially rectangular in shape , and configured to limit a space 3 from the environment . The structure 2 further defines two openings 3a, 3b configured to allow the fluidic communication of space 3 with first and second openings O' , O' ' of structure B . Accordingly, also openings 3a, 3b are aligned parallel to a longitudinal axis of the structure 2 and are preferably coplanar one with the other .

The structure 2 comprises a lateral wall 2 ’ opposite to the openings 3a, 3b and a pair of terminal walls 2 ’ ’ , 2 ’ ’ ’ namely an upper wall 2 ’ ’ and a lower wall 2 ’ ’ ’ . The aforementioned walls are connected together to define the space 3 that is separated by the environment .

The air conditioning unit 1 comprises , housed within space 3 , an air conditioning arrangement 4 configured to allow insertion through one of openings O' , O' ' of a conditioned air flow .

In particular, the air conditioning arrangement 4 comprises , inter alia, a cooling coil 5 configured to allow the cooling of an airflow passing through this latter and a first and a second ventilation means 6 , 7 configured to allow circulation of air flow within space 3 as outlined in detail below . Other details of the air conditioning arrangement 4 will not be provided since they are not pertinent to the present invention .

According to the invention, the air conditioning unit 1 is configured to be provided with a free cooling arrangement 10 , 20 configured to allow a free cooling functionality .

In particular, the free cooling arrangement 10 , 20 comprises a first and a second dampers 11 , 21 , 12 , 22 suitable to be housed within one of openings 3a, 3b of the structure 2 and a third damper 13 , 23 suitable to be housed in lateral wall 2 ' . The aforementioned dampers are configured, i f present , to control , e . g . allow or deny or partially allow, the fluidic communication, respectively, with the space 3 towards space S or to environment outside structure 2 to space 3 .

As known, such dampers may be real i zed in any suitable shape and are preferably controlled by actuator means (not shown) that can be electronically controlled via an electronic control unit (not shown) .

Such electronic control unit may automatically control or be activated by the user to provide di f ferent cooling operations as detailed below .

Furthermore , the structure 2 comprises at least a divider wall 15 configured to divide space 3 into at least two portions 3 ' , 3 ' ' wherein a first portion 3 ' houses the second ventilation means 7 and the second portion 3 ' ' houses the first ventilation means 6 and the cooling coil 5 .

The first portion 3 ' is selectively or continuously in fluid communication with the environment in order to cool down a heat exchanger making part of the air conditioning arrangement 4 and that need to be cooled to allow operation of cooling coil 5 . Further detai ls will no be provided on such aspect for brevity .

Making reference to a first embodiment of the invention, shown in figure 1 , the air conditioning unit 1 is configured to provide a cooling flow in the second opening O' ' , i . e . through the second, lower, opening 3b .

Accordingly, the cooling coil 5 is placed to occupy the entire lower opening 3b of structure 2 so as to direct the cooled air flow towards the opening O' ' . The first ventilation means 6 is configured to move air towards the lower opening 3b and the second ventilation means 7 are configured to move air from the first opening 3a towards environment

In particular, the divider wall 15 is placed so as to divide into two portions the first opening 3a each of such two portions houses respectively a first and a second damper 11 , 12 . Therefore the first damper 11 is configured to allow selective fluidic communication of the space S with the first portion 3 ' of space 3 and the second damper 12 is configured to allow selective fluidic communication of the space S with the second portion 3 ' ’ of space 3 . The third damper 13 is housed within the lateral wall 2 ’ and configured to selectively allow the communication of environment with space 3 ' ’ in a position upstream to first ventilation means 6 with respect to the air flow passing through this latter .

Making reference to a second embodiment of the invention, shown in figure 2 , the air conditioning unit 1 is configured to provide a cooling flow in the first opening O' , i . e . through the first , upper, opening 3a .

Accordingly, the cooling coil 5 is placed to occupy the entire first opening 3a of structure 2 so as to direct the cooled air flow towards the opening O' . The first ventilation means 6 is configured to move air towards the upper opening 3a and the second ventilation means 7 are configured to move air from space 3 towards environment

In particular, the divider wall 15 is placed so as to not interfere with cooling coil 5 , i . e . so that the cooling coil 5 is entirely in second portion 3 ' ’ as mentioned above .

The arrangement according to the second embodiment further comprises a second divider wall 25 configured to divide into two portions the first opening 3a each of such two portions houses respectively a first and a second damper 11 , 12 . In particular, such second divider wall 25 divides the second portion 3 ' ’ from a further third portion 3 ' ’ ’ that is in fluid communication with the environment via a third opening 3c reali zed in the lower terminal portion 2 ’ ’ ’ .

Preferably, as shown, the second divider wall 25 is L- shaped so as not interfere with air conditioning arrangement 4 .

In particular, the first damper 21 is configured to allow selective fluidic communication of the space S with the second portion 3 ' 9 of space 3 and the second damper 22 is configured to allow selective fluidic communication of the space S with the third portion 3 ’ ’ ’ of space 3 , i . e . to environment . The third damper 23 is housed within the lateral wall 2 ’ and configured to selectively allow the communication of environment with space 3 ’ ’ in a position upstream to first ventilation means 6 with respect to the air flow passing through this latter .

The operation of the first embodiment of the invention as described above is the following .

In a first operative condition, schemati zed in figure 3A, a so-called "mechanical cooling" the second damper 12 is opened while the first and third dampers 11 , 13 are closed . The first ventilation means 6 are controlled to suck an air flow from space S and provide such air flow, cooled via cooling coil 5 operated via air cooling arrangement 4 , back within space S . The second ventilation means 7 are controlled to suck air from environment to cool down the other operative elements of the air cooling arrangement 4 . Such operative condition is indicated i f the temperature in environment is greater than the temperature required in space S .

In a second operative condition, schemati zed in figure 4A, a so-called " free cooling" the second damper 12 is closed while the first and third dampers 11 , 13 are opened . The first ventilation means 6 are controlled to suck an air flow from environment via third damper 13 and provide such air flow, within space S . The overpres sure air flow is sucked by second ventilation means 7 that flow out the latter into environment . Such operative condition is indicated i f the temperature in environment is lower than the temperature required in space S .

In a third operative condition, schemati zed in figure 5A, a so-called "partial free cooling" the all the dampers 11 , 12 and 13 are opened . The first ventilation means 6 are controlled to suck an air flow from environment via third damper 13 and provide such air flow, within space S . The overpressure airflow is partially sucked by second ventilation means 7 that flow out the latter into environment and partially sucked by first ventilation means 6 that flow back this latter to the air flow sucked from the third damper 13 . Such operative condition is indicated i f the temperature in environment is lower than the temperature required in space S over a predetermined threshold .

In a fourth operative condition, schemati zed in figure 6A, a so-called "mechanical and free cooling" the second damper and third dampers 12 , 13 are opened while the first dampers 11 is closed . The first ventilation means 6 are controlled to suck an air flow from the environment and provide such air flow, cooled via cooling coil 5 operated via air cooling arrangement 4 , back within space S . The second ventilation means 7 are controlled to suck air from environment to cool down the other operative elements of the air cooling arrangement 4 . Such operative condition is indicated i fthe external temperature is not low enough to cool the room S to the required temperature . The advantage is that the energy absorbed by the mechanical cooling is lower than with complete cooling .

The operation of the second embodiment of the invention as described above is the following .

In a first operative condition, schemati zed in figure 3B, a so-called "mechanical cooling" first damper 21 is opened while the second and third dampers 22 , 23 are closed . The first ventilation means 6 are controlled to suck an air flow from space S and provide such air flow, cooled via cooling coil 5 operated via air cooling arrangement 4 , back within space S . The second ventilation means 7 are controlled to suck air from environment to cool down the other operative elements of the air cooling arrangement 4 . Such operative condition is indicated i f the temperature in environment is greater than the temperature required in space S .

In a second operative condition, schemati zed in figure 4b, a so-called " free cooling" the first damper 21 is closed while the second and third dampers 22 , 23 are opened . The first ventilation means 6 are controlled to suck an air flow from environment via third damper 13 and provide such air flow, within space S . The overpressure air flow naturally flows out via third opening 3c into environment . Such operative condition is indicated i f the temperature in environment is lower than the temperature required in space S .

In a third operative condition, schemati zed in figure 5B, a so-called "partial free cooling" the all the dampers 21 , 22 and 23 are opened . The first ventilation means 6 are controlled to suck an air flow from environment via third damper 23 and provide such air flow, within space S . The overpressure airflow is partially sucked by first ventilation means 6 that flow back this latter to the air flow sucked from the third damper 23 . The overpressure air flow naturally flows out via third opening 3c into environment . Such operative condition is indicated i f the temperature in environment is lower than the temperature required in space S over a predetermined threshold .

In a fourth operative condition, schemati zed in figure 6B, a so-called "mechanical and free cooling" the first dampers 21 is closed and the second damper and third dampers 22 , 23 are opened . . The first ventilation means 6 are controlled to suck an air f low from the environment and provide such air flow, cooled via cooling coil 5 operated via air cooling arrangement 4 , back within space S . The second ventilation means 7 are controlled to suck air from environment to cool down the other operative elements of the air cooling arrangement 4 . The overpressure air flow naturally flows out via third opening 3c into environment Such operative condition is indicated i f the external temperature is not low enough to cool the room S to the required temperature . The advantage is that the energy absorbed by the mechanical cooling is lower than with complete cooling .

In view of the foregoing, the advantages of an air conditioning unit 1 according to the invention are apparent .

The use of a common structure for both upper and lower blow of cooled airflow and for " free-cooling" and " standard" arrangement allow a great economy in fabrication of the air conditioning unit .

Indeed, there is only need to arrange the operative element of the air conditioning arrangement within the air conditioning unit and to provide , i f needed, the dampers and the divider walls to provide high number of di f ferent configuration with the same common structure .

Accordingly, the proposed common structure allow economy of scale , less time for manufacturing and is versatile .

It is clear that modi fications can be made to the described air conditioning unit 1 which do not extend beyond the scope of protection defined by the claims . For example , the shapes of the unit 2 and the internal arrangement of air refrigeration apparatus may vary according to their dimension and the needs of the unit 2 .

Similarly, the dampers are schemati zed but they can be reali zed as preferred, as on-of f dampers or proportional dampers .