ITBO20090324A1 - SYSTEM TO HYGIENIZE AND / OR CLEAN A HEAT EXCHANGER - Google Patents

Description

â € œSYSTEM FOR SANITIZING AND / OR CLEANING A HEAT EXCHANGERâ €

The present invention relates to a system for sanitizing and / or cleaning a heat exchanger.

In particular, the present invention finds advantageous, but not exclusive application in the sanitation and / or cleaning of the heat exchanger of an indoor or outdoor unit of an air conditioning system that can be installed inside buildings, to which the following description will explicitly refer without losing in general.

An air conditioning system for a building, for residential or industrial use, normally includes one or more indoor units, each of which is located in one room of the building and is equipped with a respective heat exchanger to absorb the heat of the building. Ambient air, and an outdoor unit, which includes a refrigeration unit to cool and circulate, along a service circuit that connects the internal units to the refrigeration unit, a refrigerant fluid, for example a liquid-based refrigerant substantially of water (industrial plants) or a refrigerant gas (residential plants). Each heat exchanger, both that of the indoor units and that of the outdoor unit, basically consists of a finned pack crossed by a coil, in which the refrigerant fluid circulates. The set of surfaces of the fins of the finned pack constitute the heat exchange surface of the exchanger. Each indoor or outdoor unit is equipped with a fan to force the circulation of air through the finned pack of the relative heat exchanger.

The forced circulation of air through the heat exchanger favors the deposition of dust on the fins of the finned pack and the heat exchange process favors the formation of condensation on the fins. The presence of dust and condensation creates an ideal environment for the growth of impurities, such as molds and bacteria, which are then transported by the air circulating between the fins. Therefore, periodic cleaning of the exchanger is necessary in order not to compromise its performance and the healthiness of the air in the rooms. Normally, the heat exchanger is cleaned once a year. Cleaning is performed manually by a maintenance technician, who opens the fairing of the indoor or outdoor unit to access the exchanger and sprays suitable substances on the finned pack.

Among the impurities that are deposited in the finned pack there are molds and bacteria. Unfortunately, an annual cleaning is inadequate to remove bacteria and molds which, if they remain on the exchanger even for a few days, can cause respiratory diseases. More frequent manual cleaning, for example monthly, of the heat exchangers to sanitize them is however very expensive

The object of the present invention is to provide a system for sanitizing a heat exchanger, which system can be easily installed on the heat exchanger and, at the same time, is easy and economical to produce.

In accordance with the present invention, a system and a method are provided for sanitizing or cleaning a heat exchanger of an air conditioning system as defined in the attached claims.

The present invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 schematically illustrates the system for sanitizing a heat exchanger of an indoor unit of an air conditioning system, which system is made according to the dictates of the present invention;

Figure 2 illustrates, according to a perspective view, the arrangement of some elements of the system of Figure 1 with respect to the heat exchanger;

Figure 3 illustrates, according to a side view, the arrangement of some elements of the system of Figure 1 with respect to the heat exchanger;

Figure 4 illustrates, according to a side view, the arrangement, with respect to the heat exchanger, of some elements of the system for sanitizing a heat exchanger according to a further embodiment of the invention; And

Figure 5 schematically illustrates the system for sanitizing a heat exchanger according to a further embodiment of the invention.

In figure 1, the number 1 indicates an indoor unit of a known air conditioning system (not shown) that can be installed in a building. The indoor unit 1 comprises a heat exchanger 2 substantially constituted by a finned pack 3 crossed by a coil 4, in which the cooling fluid circulates coming from the refrigerating machine (not shown) of the air conditioning system. The surface of the set of fins of the finned pack 3 define the heat exchange surface of the heat exchanger 2. The indoor unit 1 includes, among other things, a fan (not shown) to force the circulation of air through the finned pack 3 and a control unit 5 to control the operation of the indoor unit 1 itself, for example to electrically power the fan and control its rotation speed on command of a user.

In figure 1, the number 6 indicates the system for sanitizing the heat exchanger 2, which system 6 is made in accordance with the invention.

With reference to Figure 1, the system 6 comprises at least one tank 7 for storing a sanitizing substance and at least one nebulizing unit 8, which is adapted to nebulize the sanitizing substance and to be arranged in front of the heat exchanger 2 so as to distribute the atomised substance over the entire heat exchange surface of the heat exchanger 2. Advantageously, the system 6 comprises a plurality of atomising units 8 so as to increase the uniformity of distribution of the atomised substance on the heat exchange surface of the heat exchanger 2 Figure 1 illustrates an example of a system 6 comprising four nebulizing units 8.

The system 6 also comprises a dispensing device 9 for withdrawing the substance from the tank 7 and dispensing the substance to the nebulising units 8, and a coupling device 12 of the quick-coupling type, which is interposed between the tank 7 and an inlet 13 for the substance of the dispensing device 9 to allow the tank 7 to be moved to and from a normal operating position of structural coupling of the tank 7 to the inlet 13 of the dispensing device 9.

In particular, the dispensing device 9 comprises a pump 10 having an inlet coinciding with the inlet 13 to suck the substance directly from the tank 7 through the inlet 13, and a distribution circuit 11 connecting an outlet 10a of the pump 10 to the nebulising units 8. The pump 10 is adapted to suck the substance from the tank 7 and to introduce the substance into the distribution circuit 11, through which the substance is distributed to the dispensing units 8. Furthermore, the dispensing device 9 comprises a sampling duct 13a connected to the inlet 13 and extending towards the bottom 7a of the tank 7 when the latter is in the operating position so that the pump 10 can withdraw substantially all the substance contained in the tank 7.

Finally, the system 6 comprises a level sensor 14 to detect the exhaustion of the substance in the tank 7, a removal sensor 15 to detect the removal of the tank 7 from the operating position, and a control unit 16 configured to control the delivery device 9, and in particular the pump 10, as a function of the signals supplied by the sensors 14 and 15 and as a function of programmable parameters on the control unit 16 itself.

Pump 10 is known per se and therefore not described in further detail. The distribution circuit 11 is structured in bifurcations, i.e. it doubles repeatedly ending with a plurality of ducts 11a associated, each, with a respective nebulizer unit 8.

Each nebulizer unit 8 comprises a respective nozzle 17 having a nebulization opening cone suitably sized according to the size of the heat exchanger 2 and the number of nebulizing units 8, i.e. the number of nozzles 17. Each nozzle 17 has an outlet opening 18 (figure 3) having a smaller section than that of the distribution circuit 11 to increase the pressure of the substance arriving from the distribution circuit 11 to such an extent as to nebulize the sanitizing substance that comes out of the nozzle 17. Therefore, this nebulizer unit 8 performs a pneumatic nebulization of the substance. The nozzle 17 is of a known type and therefore is not described in further detail.

Figure 2 illustrates, according to a perspective view, an example of arrangement of the nebulising units 8 with respect to the heat exchanger 2. In particular, figure 2 shows the nebulising units 8, the distribution circuit 11 and a container 19 which encloses the others components (not visible in figure 2) of the system 6, such as the pump, the tank 7, the control unit 16, the sensors 14 and 15 and the coupling device 12. The nebulising units 8 are arranged in front of a larger face 21 of the heat exchanger 2. Furthermore, the nebulising units 8 are arranged at the same distance from the larger face 21. Considering that the heat exchanger 2 has an overall dimensions substantially in the shape of a rectangular parallelepiped, ie in the shape of a parallelepiped with rectangular faces, the larger face hereinafter means one of the two larger-area faces of the heat exchanger 2. In particular, the nebulising units 8 are d located in front of a lateral longitudinal portion 20 of a major face 21 of the heat exchanger 2 and at the same distance from the longitudinal portion 20. In the example of arrangement of figure 2, the longitudinal portion 20 is defined along an upper edge of the heat exchanger 2. The nozzles 17 of the nebulizing units 8 are turned towards the larger face 21 so as to deliver the substance from the top downwards.

Normally, the indoor unit 1 comprises an external casing, known and not illustrated for clarity, which covers the heat exchanger 2 and the other components of the indoor unit 1 and which has a portion provided with slits in correspondence with the heat exchanger 2. The Nebulizing units 8 are adapted to be arranged between the external casing and the heat exchanger 2. The distance between the nebulising units 8 and the heat exchanger 2 essentially depends on the space available between the heat exchanger 2 and the external casing. .

Figure 3 illustrates a side view of the example of arrangement between the nebulising units 8 and the heat exchanger 2 of Figure 2. The nebulising units 8 are arranged at a distance D from the longitudinal portion 20. The nozzle 17 of each Nebulizer unit 8 has a delivery axis 22. The heat exchanger 2 illustrated in Figures 2 and 3 extends parallel to a plane 23, which is transverse to a vertical plane 24. Each nozzle 17 is arranged with the outlet opening 18 facing the longer face 21 of the heat exchanger 2 at the distance D from the longitudinal portion 20.

Advantageously, the distance D is less than 2 cm. Furthermore, the delivery axis 22 of the nozzle 17 obliquely intercepts the plane 23 forming an angle 25. The value of the angle 25 depends on the nebulization cone of the nozzle 17. In this way, the substance atomised is distributed uniformly on face 21, and therefore on the whole heat exchange surface of the heat exchanger 2. Advantageously, the value of angle 25 is between 30 ° and 60 °.

With reference again to Figure 1, the coupling device 12 allows the tank 7 to be retained in a releasable manner in the operative position of coupling with the inlet 13 of the dispensing device 9. Finally, the coupling device 12 allows to quickly remove tank 7 from its operating position, for example when tank 7 is empty. The coupling device 12 comprises an element 12a integral with the inlet 13 of the dispensing device 9 and another element 12b integral with the tank 7 and able to couple to the element 12a, for example by screwing a quarter of a tour. In the example of figure 1, the element 12a includes a cylindrical mouth internally threaded and the element 12b has a cylindrical shape and is threaded on the outside to be able to screw, for a quarter of a turn, into the cylindrical mouth of element 12a. The removal sensor 15 is arranged in the coupling device 12, for example mounted on the element 12a integral with the pump 10, and comprises, for example, an electrical micro-contact of the normally open type adapted to close when the tank 7 It is in the operating position and opens when the reservoir 7 is removed from the operating position.

The level sensor 14 is constituted by a known type of conduction level sensor, that is of the type exploiting the conductivity of the substance contained in the tank 7. The level sensor 14 is able to be positioned at a certain height H from the bottom 7a of tank 7 when the latter is in the operating position. The height H actually determines the minimum level below which the level sensor 14 signals the exhaustion of the substance in the tank 7. In particular, the level sensor 14 is mounted at the lower end of a rod 26, which is integral with the element 12a of the coupling device 12 and is able to extend towards the bottom 7a of the tank 7 when the latter is in the operative position.

The control unit 16 is adapted to be electrically connected to the control unit 5 of the indoor unit 1 to receive the electrical power supply and an ignition signal directly from the control unit 5 itself. In other words, when the user switches on the indoor unit 1, he automatically activates the control unit 16 and then automatically switches on the system 6 as well.

Advantageously, the control unit 16 comprises a remote ignition module 27 to allow the user to remotely activate or deactivate the system 6 independently of the operating status (on / off) of the indoor unit 1.

The control unit 16 comprises an electronic printed circuit board (not shown), which comprises a microcontroller 28 of a known type programmed to control the delivery device 9, i.e. to control the pump 10, according to the signals supplied by the removal 15 and from the level sensor 14 and according to user programmable parameters. The electronic board of the control unit 16 also comprises mini-switches 29 for programming the programmable parameters in hardware mode. The control unit 16 also comprises an indicator light 30 consisting of an LED to signal to the user the exhaustion of the substance in the tank 7.

The programmable parameters include a TPS substance dispensing period, ie the period with which the dispensing is periodically repeated, and the substance dispensing duration TS of each repetition of dispensing. For example, the TPS delivery period is programmable in the range of values between 1 and 24 hours. Advantageously, the TPS delivery period can be selected within a set of values comprising 1 hour, 3 hours, 6 hours, 12 hours and 24 hours. The duration of dispensing TS actually determines the quantity of substance to be dispensed at each repetition of dispensing and the quantity of substance to be dispensed depends on the size of the heat exchanger 2 and depending on the environment of use of the indoor unit 1. Keeping taking these aspects into account, the duration of delivery TS is programmable in the range of values between 10 and 200 seconds.

According to a further aspect of the present invention, the microcontroller 28 of the control unit 15 is programmed to operate the system 6 in the following way.

In use, the switching on of the indoor unit 1 automatically causes the switching on of the system 6. Once the system 6 is switched on, the control unit 16 periodically switches on, according to the pre-established TPS delivery period, the dispensing 9, ie it periodically switches on the pump 10, for a duration equal to the predetermined dispensing duration TS so as to periodically repeat the dispensing of a certain quantity of sanitizing substance. The dispensed quantity of sanitizing substance runs through the distribution circuit 11 up to the nebulizing units 8, which cause the nebulization of the sanitizing substance.

The control unit 16 continuously monitors the signals supplied by the sensors 14 and 15. When the substance in the tank 7 is exhausted, i.e. when the quantity of residual substance is below the minimum level, the level sensor 14 signals this event to the control unit 16, which consequently turns on the indicator light 31 to signal to the user that the tank 7 is empty and to control the dispensing device 9 so as to inhibit the dispensing of the substance to prevent the dispensing device 9, when running idle, it will be damaged. The replacement of the empty tank 7 with a full tank 7 causes the temporary removal of the tank 7 from the operating position. The removal sensor 15 signals the event of removal of the tank 7 to the control unit 16, which restores the periodic dispensing of the substance according to this event.

According to an embodiment (not shown) of the invention, the level sensor 14 consists of a known type float sensor.

According to a further embodiment (not shown) of the invention, the control unit 16 has no mini-switches 29 and comprises a keyboard to allow the user to program the programmable parameters in a software way. In use, the user enters, via the keyboard, the desired values for the parameters to be programmed and the entered values are stored in a non-volatile internal memory of the microcontroller 28.

According to a further embodiment (not shown) of the invention, the system 6 comprises an electric battery for electrically powering the control unit 16 and the dispensing device 9 independently of the control unit 5 and a coupled micro-contact with the mechanism for opening the air deflectors of the indoor unit 1 to generate the ignition signal of the control unit 16. Therefore, this embodiment does not require the connection between the control unit 16 and the control unit 5 of the unit internal 1.

According to a further embodiment of the invention illustrated in Figure 4, in which the corresponding elements are indicated with the same numbers and abbreviations of Figure 3, the longitudinal portion 20 is defined along a lower edge of the heat exchanger 2. The nozzles 17 of the nebulizing units 8 are turned towards the greater face 21 so as to deliver the substance from the top down towards the top.

According to a further embodiment (not shown) of the invention, each nebulizer unit 8 comprises, instead of the nozzle 17, a respective piezoelectric transducer for nebulizing the sanitizing substance by means of ultrasounds.

According to a further embodiment of the invention illustrated in Figure 5, in which the corresponding elements are indicated with the same numbers and abbreviations of Figure 1, the distribution circuit 11 is connected directly between the input 13 of the dispensing 9 and the nebulizing units 8 and the dispensing device 9 comprises, instead of the pump 10 of Figure 1, a compressor 31 for compressing air inside the tank 7 so as to push the substance out of the tank 7 through the sampling duct 13a , and therefore through the inlet 13, and then introduce the substance into the distribution circuit 11. More in detail, the dispensing device 9 comprises a further duct 32, having an end suitable to be arranged inside the tank 7 when the latter is in the operating position and the other end is connected to an outlet 31a of compressor 31. Compressor 31 introduces a component of compressed air which over poses to the nebulized substance, favoring the distribution of the substance over the entire heat exchange surface of the heat exchanger 2. Each nebulizing unit 8 is of the type including the nozzle 17. The control unit 16 is configured to control the device supply 9, ie the compressor 31, and in particular the compressor 31, as a function of the signals supplied by the sensors 14 and 15 and as a function of the programmable parameters.

From what has been described above, it is clear that system 6 can also be used to nebulize other types of substances with different purposes, for example a detergent substance, or a deodorant substance or a substance composed of several components, for example a sanitizing substance and detergent, or a sanitizing and deodorizing substance, or again a sanitizing, detergent and deodorizing substance. Depending on the type of substance contained in the tank 7, the system 6 will allow to sanitize, clean or deodorize the heat exchange surface of the heat exchanger 2 or it will allow to sanitize and deodorize, or even sanitize, cleanse and deodorize the heat exchange surface of the heat exchanger 2.

According to a further embodiment (not shown) of the present invention, the system 6 is used to clean a heat exchanger. According to this embodiment, the tank 7 stores a predominantly detergent substance and the dispensing device 9 is of the type comprising the compressor 31 and the system 6 operates as in the embodiment with the compressor 31 described above. In particular, the compressor 31 introduces a component of compressed air which is superimposed on the nebulized detergent substance, favoring the removal of dirt from the heat exchanger. This embodiment is particularly advantageous for cleaning the heat exchanger of an outdoor unit of an air conditioning system. In fact, a large amount of dirt quickly deposits on the finned pack of the heat exchanger of the outdoor unit as the outdoor unit normally works outside buildings and is equipped with a very powerful forced ventilation system.

Claims (11)

CLAIMS 1. System for sanitizing or cleaning a heat exchanger (2) of an air conditioning system, the system (6) comprising: at least one tank (7) for storing a sanitizing or detergent substance; at least one nebulizer unit (8), which is able to nebulize the substance and to be arranged in front of the heat exchanger (2) so as to distribute the nebulized substance over the entire heat exchange surface of the heat exchanger (2 ); dispensing means (9) for withdrawing the substance from the tank (7) and delivering the substance to the nebulizer unit (8); coupling means (12) interposed between the tank (7) and an inlet (13) of the dispensing means (9) to allow the tank (7) to be moved from and towards a normal operating position of structural coupling of the tank (7) to said inlet (13); first sensor means (14) for detecting the exhaustion of the substance in the tank (7); second sensor means (15) for detecting the removal of the tank (7) from said operating position; and control means (16) configured to control the delivery means (9) as a function of the signals supplied by the first and second sensor means (14, 15) and as a function of programmable parameters on the control means (16). System according to claim 1, wherein said at least one nebulizer unit (8) comprises a respective nozzle (17). System according to claim 1, wherein said at least one nebulizer unit (8) comprises a respective piezoelectric transducer. System according to any one of claims 1 to 3, wherein said dispensing means (9) comprise a pump (10) having an inlet coincident with said inlet (13) of the dispensing means for sucking said substance directly from said tank (7) through said inlet (13). System according to claim 1 and 2, wherein said delivery means (9) comprise a compressor (31) for compressing air inside said tank (7) so as to push said substance out of the tank (7) through said inlet (13). System according to any one of claims 1 to 5, wherein said first sensor means (14) comprise a conduction level sensor. System according to any one of claims 1 to 5, wherein said first sensor means (14) comprise a float level sensor. System according to any one of claims from 1 to 7, wherein said second sensor means (15) comprise an electrical contact of the normally open type, able to close when said tank (7) is in the operative position and to open when the tank (7) is removed from said operative position. System according to any one of claims 1 to 8, wherein said programmable parameters comprise a substance delivery period (TPS) and a substance delivery duration (TS) for each periodic repetition of the delivery. 10. Method for sanitizing or cleaning a heat exchanger (2) of an air conditioning system, the method comprising the steps of: - storing a sanitizing or detergent substance in at least one tank (7); - coupling the tank (7) to substance dispensing means (9) so as to be able to move the tank (7) from and towards an operative position of structural coupling of the tank (7) to the dispensing means (9); - withdrawing from the tank (7) and dispensing a certain quantity of the substance through said dispensing means (9); - nebulising, by means of nebulizing means (8) arranged in front of the heat exchanger (2), the dispensed substance; - detect, by means of level sensor means (14), the exhaustion of the substance in the tank (7); - inhibit the dispensing of the substance when the substance in the tank (7) is exhausted; - detecting, by means of removal sensor means (15), the event of removal of the tank (7) from said operating position; And - restore the supply of the substance according to the event of removal of the tank (7). Method according to claim 10, wherein the dispensing of said quantity of the substance is repeated periodically according to a predetermined dispensing period (TPS); the duration of each periodic repetition of the disbursement being equal to a predetermined disbursement duration (TS).