BE1030293A1 - AIR CONDITIONING SYSTEM AND METHOD FOR ESTABLISHING A CONTROL LOGIC FOR OPERATING THE SHUT-OFF VALVE - Google Patents

Abstract

The present invention relates to an air conditioning system comprising a compressor unit connected to a plurality of indoor units by means of a plurality of pipes; a switching unit between the outdoor unit and each indoor unit, the switching unit comprising a number of shut-off valves; a multitude of leak detection sensors; and a controller configured to control the plurality of shutoff valves and have information to associate each of the shutoff valves with at least one sensor. To manage refrigerant leaks safely and efficiently, the shut-off valves are operated based on information from their linked sensors.

Description

AIR CONDITIONING SYSTEM AND METHOD OF ESTABLISHMENT

PROVIDING A CONTROL LOGIC FOR OPERATING THE

SHUT-OFF VALVE

FIELD OF INVENTION

The present invention relates to air conditioning systems. In particular, the present invention relates to safety devices and methods for air conditioning.

BACKGROUND

Air conditioning systems often consist of numerous individual elements that can develop leaks. Refrigerants used in air conditioning systems are often harmful to the environment, health or both. Setting up and monitoring modern air conditioning systems, especially in larger buildings, is therefore extremely difficult.

EP 2570740 first discloses a switching unit in which several shut-off valves are integrated. Each of the inlet shutoff valves and at least one corresponding outlet shutoff valve are paired as an integral body, and a plurality of pairs are grouped together.

EP 3270069 describes a switching unit for cooling/heating that can detect refrigerant leaks. In some embodiments disclosed in the document, switching units are provided near indoor units, which switching units are provided with sensors for detecting coolant leaks.

The detection range revealed in both papers is quite narrow and thus does not provide absolute detection reliability. More importantly, the devices and systems described in the aforementioned documents do not guarantee user safety.

The present invention aims to find a solution for at least some of the above-mentioned problems and disadvantages. The aim of the invention is to provide a method that eliminates these disadvantages.

© BE2022/5125

There is therefore a need for a system that makes it possible to detect and repair any leaks in the said system completely, reliably and efficiently,

SUMMARY OF THE INVENTION

The present invention and embodiments thereof serve to provide a solution for one or more of the above-mentioned disadvantages. To this end, the present invention relates to an automatic payment system with security features.

Unless otherwise defined, all terms used in disclosing the invention, including technical and scientific terms, have the meanings commonly understood by one of ordinary skill in the art to which this invention belongs. By way of further guidance, definitions are included to better appreciate the teachings of the present invention.

As used herein, the following terms have the following meanings: “A,” “the,” and “it,” as used herein, include both singular and plural referents unless the context clearly indicates otherwise. By way of example, 'a sub-fund' refers to one or more sub-funds, 'Comprise', 'comprising' and 'comprises' and 'existing owl' as used herein are synonymous with 'contain', 'containing' or 'containing' and are inclusive or open terms that specify the presence of what follows (e.g., a component) and imply the presence of additional, non-inclusive components, features, elements, parts, steps, which are well known in the art or described therein , not off,

Furthermore, the terms first, second, third and the like are used in the description and conclusions to distinguish similar elements and not necessarily to describe a sequence, neither temporal nor spatial, unless otherwise indicated. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the invention described herein are capable of operating in any order other than that described or shown herein.

3 BE2022/5125

Circulating numerical ranges by endpoints includes all numbers and fractions included within that range, as well as the named endpoints.

While the terms 'one or more' or 'at least one', such as one or more or at least one member of a group of persons, is self-evident, by further explanation the term includes, among other things, a reference to one of the members, or to two or more of the members, such as for example any >3, 24, 25, 26 or 27 etc. of the members, and to all mentioned members. i0 Unless otherwise defined, all terms used in disclosing the invention, including technical and scientific terms, have the meanings commonly understood by one of ordinary skill in the art to which this invention belongs. BH means of further guidance, definitions for the terms used in the description are included to better appreciate the teachings of the present invention. The terms or definitions used herein are solely intended to assist in the understanding of the invention.

Reference throughout this specification to "one embodiment" or "an embodiment" means that a specific feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, occurrences of the phrases "in one embodiment" or "in an embodiment" at various places throughout this specification do not necessarily all refer to the same embodiment, but may do so. Furthermore, the specific features, structures or characteristics may be combined in any suitable manner, as would be apparent to one skilled in the art based on this disclosure, in one or more embodiments. Furthermore, while some embodiments described herein include some, but not other, features included in other embodiments, combinations of features of different embodiments are intended to be within the scope of the invention, and constitute different embodiments, as would be understood by those skilled in the art . For example, in the following claims, any of the claimed embodiments may be used in any combination.

In a first aspect, the invention relates to an air conditioning system comprising:

+ BE2022/5125 a compressor unit connected to multiple indoor units by means of multiple pipes; a switching unit between the compressor unit and each indoor unit, this switching unit comprising a plurality of shut-off valves connected to each pipe or pipe branch leading to an indoor unit; a multitude of leak detection sensors; and a controller configured to control the plurality of shut-off valves and have information to associate each of the shut-off valves with at least one leak detection sensor; characterized in that the shut-off valve is operated on the basis of a signal from the coupled sensor.

In this system, the controller has information about associating each of the shutoff valves with at least one leak detection sensor, so that when a refrigerant leak is detected by a leak detection sensor, based on the information from that leak detection sensor, the controller is configured to control a shutoff valve that is linked to the leak detection sensor. Therefore, for example, when a leak detection sensor located in a room where no indoor unit is installed and only the pipe passing through the room detects refrigerant leakage, the controller is configured to close a shutoff valve associated with the leak detection sensor, based on the signal from the leak detection sensor.

In this system, the shut-off valves are operated based on information from the linked leak detection sensors. Preferably, an intermediate device is provided to mediate information from the leak detection sensors and the operation of the shut-off valves.

In this context, the terms "linking" or "linked" as applied to elements of the system should be understood as an assignment or registration of one or more elements to each other. Elements that are linked together are defined as having a function or effect that in turn directly influences the function and/or condition of any other element linked to that element. For example, a leak may occur in a pipe that runs through a room, which leak will increase the coolant concentration in that room and will therefore activate a leak detection sensor, which leak detection sensor will close a shut-off valve, which shut-off valve is in direct connection with the pipe. In this example, the shut-off valve and the leak detection sensor are said to be coupled together.

In this context, the term 'indoor unit' should be understood as an indoor air conditioning unit.

In some buildings, not all rooms have an indoor unit. However, leaks do not only occur in or next to indoor units. In a preferred embodiment, each space that has an indoor unit and/or that is crossed by at least one of the refrigerant-carrying pipes is provided with at least one leak detection sensor. In this way, the detection capabilities are extended to any potential source of leakage in the system, as each element of the system must be connected by at least one refrigerant-carrying pipe,

In a further or different embodiment, the switching unit is a manifold configured to connect to the compressor unit and distribute a refrigerant input to multiple pipe branches. The switching unit is preferably placed before any subdivisions in the piping. This makes it easier to tackle specific potentially leaking pipes/indoor units in the event of refrigerant leakage than if the switching unit is not a manifold. This way, the air conditioning system can still function at a reduced capacity by serving areas not reached by potentially leaking ducts.

In a further or different embodiment, the leak detection sensors are installed outside the indoor units. In this way, the leak detection sensors are free from the enveloping effect created by the structure of cemented indoor units.

This allows refrigerant leaks from sources other than indoor units to reach the sensors more easily, while leaks from indoor units can still be detected.

In a further or different embodiment, each pulse detection sensor is linked to a room in which it is placed. The links are provided to or are known by the controller. This link is accomplished by assigning each leak detection sensor a unique unit identification code and assigning this code to the room or area code in which the leak detection sensor is installed.

This connection can be done manually. Preferably that link will be

> BE2022/5125 is performed automatically, which has the advantage that human errors in the pairing process can be reduced or even eliminated.

In a further or different embodiment, each pipe or pipe branch is coupled to a shut-off valve. Said shut-off valve is capable of blocking or allowing refrigerant to flow to said pipe or pipe branch. This connection is carried out by means of a unique pipe or pipe branch identification code and a unique shut-off valve identification code. Preferably, the code of a pipe or branch is linked to the code of the shut-off valve from which the pipe originates. This link is provided to or is known by the controller.

In a further or different embodiment, each space that has an indoor unit and/or that is crossed by at least one of the pipes is connected to at least one shut-off valve. Preferably, each room that has an indoor unit and/or that is crossed by at least one of the pipes, will be connected to one shut-off valve per pipe that crosses this room. This connection is provided by or is known by a controller. This makes it advantageously allows not only to stop any leaks that may occur in the space, but also allows the cause of the leak to be diagnosed, for example by flowing refrigerant to one pipe at a time and measuring the concentration of refrigerant in the monitor space.

Other elements that are potential sources of leakage are the switching unit and the compressor units. In some cases the switching unit will be placed in a building. In this case, the switching unit is preferably placed in a ventilated room. A leak detection sensor is preferably placed in the room in which the switching unit is located. More preferably, the room is ventilated by a fan, which fan is further connected to a controller, which controller is further connected to the leak detection sensor installed in the room. This allows refrigerant leaking from the switching unit to be drained from the ventilated area.

In cases where the compressor unit must be placed in a building, the compressor unit is preferably placed in a ventilated room. More preferably, a leak detection sensor is placed in the room. Even more preferably, the room is ventilated by a fan, which fan is further away

7 BE2022/5125 connected to a controller and which controller is further connected to the leak detection sensor installed in the room.

In the event that both a switching unit and a compressor unit must be installed in a building, the switching unit and the compressor unit are preferably placed in the same ventilated space. Depending on the dimensions of the ventilated space, this can reduce the number of leak detection sensors required, while maintaining a level of safety comparable to a situation where both units were in separate ventilated spaces.

In a further or different embodiment, each sensor is configured to close the shut-off valves associated with any space that has an indoor unit and/or that is crossed by at least one of the pipes. For example, the sensors are connected to a central controller, which controller is configured to receive signals from leak detection sensors and interpret these signals into signals for closing a shut-off valve,

In a further or different embodiment, a refrigerant used in the air conditioning system is CO2 or R466A. These refrigerants are advantageously non-flammable and have a density much heavier than air. These refrigerants have a very predictable trajectory and pooling properties, making the leak detection sensor easy to use. can be installed and leaks can be consistently detected,

A second aspect of the invention relates to a method for establishing a control logic for operating the shutter valves on the basis of a leak detection signal, comprising the steps of: registering leak detection sensors present in each room; registering pipes that run through or in each room; registering shut-off valves connected to each pipe; registering each leak detection sensor on at least one shut-off valve:

This method can be advantageously applied using a floor plan of the building in which the air conditioning system is to be installed. Preferably, the application of the current method is carried out by means of a software application that allows the user to insert, connect and edit attributes of each element (e.g. pipes, indoor units, shut-off valves) of the air conditioning system. More preferably, said software includes a graphical

6 BE2022/5125 user interface that allows the introduction and editing of data by the user. In this way, generating a set of computer- and human-readable correspondence relationships becomes easier and less prone to human error.

In a preferred embodiment, each leak detection sensor is registered to each shut-off valve associated with each pipe running through or in the space where the sensor is installed. Preferably, registration information is stored in a machine-readable tabular format. In this way the operator is provided with an easy to read report, which can be advantageously used as a system assembly/verification sheet. Being machine readable, the registration information is advantageously easy to copy, edit, download from/ to upload to a controller,

However, it is clear that the invention is not limited to this application. The method according to the invention can be applied in all kinds of systems in which liquids are transported that are or may be in a gaseous state during or shortly after leaking, and in which state those liquids are denser than air.

The invention is further described by the following non-limiting examples which further illustrate the invention and are not intended, nor should they be construed, to limit the scope of the invention.

BRIEF DESCRIPTION OF THE FIGURES

The following description of the figures of specific embodiments of the invention is exemplary only in nature and is not intended to limit the present teachings, their application or use. In all drawings, corresponding reference numerals indicate similar or corresponding parts and features,

Figure 1 shows an air conditioning system where the compressor unit is located outside the building,

Figure 2 shows an air conditioning system where the compressor unit is located inside the building and in a room separate from that of the switching unit.

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Figure 3 shows an air conditioning system where the compressor unit is located in the building and in the same room as the switching unit.

Figure 4 shows a topology of pipe routing and sensor placement for a variety of indoor units.

Figure 5 shows a flowchart of the processes that are performed once a refrigerant leak is detected.

Figure 6 shows a functional structure of the controller.

DETAILED DESCRIPTION OF THE EMBODIMENTS

With the aim of better illustrating the properties of the invention, a description is given below, as an example and in no way limiting other possible applications, of a number of preferred embodiments of the air conditioning system, wherein:

Figure 1 shows an air conditioning system 1. The air conditioning system according to the present embodiment comprises a compressor unit 2, a number of indoor units, a switching unit 3 connected between the compressor unit 2 and each indoor unit, a number of leak detection sensors and a controller. The air conditioning system according to the present embodiment is for example, an air conditioning system capable of cooling and heating using COZ or R4566A refrigerant. Figure 1 shows an air conditioning system £ where the compressor unit 2 is located outside the building. In this way, the compressor unit 2 is advantageously eliminated as a possible source of leaks. The compressor unit 2 is shown in fluid communication with the switching unit 3. The switching unit 3 includes several shut-off valves and a manifold. The switching unit 3 splits the refrigerant flow to and from the compressor unit 2. in multiple pairs bi-directional coolant connection through the manifold. Switching unit 3 is connected to an indoor unit via two pipes. The two pipes consist of a liquid pipe through which a liquid refrigerant flows and a gas pipe through which a gaseous refrigerant flows. The switching unit 3 can be connected to any of the indoor units 5 to 14. The switching unit 3 has several pairs of liquid pipe and gas pipe, which number of pairs is equal to the number of indoor units that can be connected. In this way, the control of the coolant flow is achieved

10 BE2022/5125 advantageously centralized and as far upstream as possible, which advantageously enables better control of any leakage. In this figure, each indoor unit 5 to 14 is equipped with a pair of two-way connections.

In the configuration of air conditioning system 1 shown in this figure, the switching unit 3 is shown inside the building and in a room equipped with a fan 4. This configuration makes it possible to drain any refrigerant that may leak from the switching unit 3 itself.

Figure 2 shows an air conditioning system 1 where the compressor unit 2 is located inside the building and in a room separate from that of the switching unit 3. In this figure, the room where the compressor unit 2 is installed is equipped with a second fan 15. This allows any refrigerant leaking from compressor unit 2 will be extracted before it reaches other parts of the building. The room where switching unit 3 is installed is also equipped with a first fan 4 for the possibility of a leak in or next to said switching unit 3. The compressor unit 2 is shown in fluid connection with switching unit 3, which switching unit splits the refrigerant flow to and from the compressor unit 2 into multiple pairs of bi-directional refrigerant connections. In this way, any leaks can be stopped far upstream, eliminating the risk of dangerous amounts of refrigerant in one of the rooms! accumulate is limited. In this figure, each indoor unit 5 to 14 is equipped with a pair of two-way connections.

Figure 3 shows an air conditioning system 1 where the compressor unit 2 is located in the building and in the same room as the switching unit 3. In this configuration only a first fan 4 is needed. This advantageously allows for simplification of the system while still maintaining sufficient refrigerant extraction capacity. In the event that either compressor unit 2 or switching unit 3 develops a leak, Compressor unit 2 is shown in fluid communication with switching unit 3, which switching unit controls the refrigerant flow from and to the compressor unit 2 splits into several pairs of bi-directional refrigerant connection. This way, any leaks can be stopped far upstream, limiting the risk of dangerous amounts of refrigerant accumulating in any of the rooms. In this figure each indoor unit

B to 14 equipped with a few two-way connections.

Figure 4 shows a topology of the equipment on the use side of the air conditioning system in Figure 1 on the plan 31. Figure 4 shows a

N BE2022/5125 topology of pipe routing and placement of leak detection sensors for multiple indoor units in a floor plan 31. The figure shows an example where multiple shut-off valves are installed in switching unit 3. The switching unit 3 comprises a number of shut-off valves (W, configured to distribute a refrigerant input through multiple pipe branches, The manifold of the present embodiment is configured to distribute the refrigerant input to four pipe branches. That is, the switch unit 3 of the present embodiment is configured to be connectable to four indoor units. controller 16 is configured to perform information processing and signal processing by executing the control program to control the operation of the shut-off valves based on signals received by any of the leak detection sensors a Um g. A configuration of the controller 16 will be explained later. The building comprises six rooms A to F. Of which, room À is equipped with an indoor unit 17, room B is equipped with indoor unit 18 and room E is equipped with indoor unit 19 and indoor unit 20. Refrigerant is distributed by switching unit 3. Refrigerant flowing through shut-off valve W is then distributed to indoor unit 17 via pipe €&. The pipe a includes two pipes connecting the indoor unit 17 to the switching unit 3. The shut-off valve W is provided in each pipe connecting the indoor unit 17 to the switching unit 3. Refrigerant flowing through shut-off valve X is distributed to the indoor unit 18 through pipe B. The pipe B comprises two pipes that connect the indoor unit 18 to the switching unit 3, the shut-off valve

X is provided in each pipe connecting the indoor unit 18 to the switching unit 3.

Refrigerant flowing through shut-off valve Y is distributed to indoor unit 19 via pipe y. The pipe y includes two pipes connecting the indoor unit 19 to the switching unit 3. The shut-off valve Y is provided in each pipe connecting the indoor unit 19 to the switching unit 3. Refrigerant flowing through shut-off valve Z is distributed to indoor unit 20 through pipe &. The pipe & includes two pipes connecting the indoor unit 28 to the switching unit 3. The shut-off valve Z is fitted in each pipe connecting the indoor unit 20 to the switching unit 3. Pipe a crosses spaces € and A, pipe B crosses spaces € and B, pipes y and & cross €, DB and E. Leak detection sensor a is shown assigned to room À, leak detection sensor b is shown assigned to room B, leak detection sensors © and d are shown assigned to room €, leak detection sensor € is shown assigned to room D and

1 BE2022/5125 leak detection sensors f and g are assigned to room E shown. The leak detection sensors a to g are installed outside the indoor units.

To process the signal sent by a leak detection sensor in case of refrigerant leakage, a correspondence relationship between each leak detection sensor and each shut-off valve must first be established through the following steps: 1. Indoor units are laid out on a building floor plan. 2. Switching unit is laid out on the floor plan of a building 3. Connect pipes between the switching unit and each indoor unit 4, Install leak detection sensors in an area where the indoor unit is located or crossed by at least one of the pipes. 5, Create Table 1 that links the unique identifiers of the sensor, room, pipe, and shut-off valve. 6, Finally, identify the correspondence between the leak detection sensor and the shut-off valve.

Table 7

Creating Table 1 that links the unique identifiers of the sensor, space, pipe, and shut-off valve can be done manually or automatically. In addition, special software can be provided to assist in its creation,

Figure 5 shows a flowchart 21 of the processes performed once a refrigerant leak is detected. A functional structure of the controller 16 is shown in Figure 6. As shown in Figure 6, the controller 16 includes an information storage 22, an information input section 23, a leak detection portion 25, an identification portion 26, a memory reading portion 27 and a signal output portion 29. The information input portion 23 is

13 BE2022/5125 configured to receive signals from all leak detection sensors connected to the controller 16. In step Si shown in Figure 5, a leak detection sensor detects a refrigerant leak. This leak detection sensor then sends a signal to the controller 16. In step S2, the leak detection section 25 receives a signal of refrigerant leakage from the leak detection sensor via the information input section 23. In step S3, the signal enables the identification section 26 to enter the unique identification number Le. the leak detection sensor from which the signal is sent. In step S4, the memory reading section 27 accesses the information storage 22 to read information related to the identified leak detection sensor. The information store 22 stores at least the information of coupling each of the shut-off valves to at least one leak detection sensor. Preferably, the information storage 22 stores the information of coupling each leak detection sensor to a room in which it is placed,

More preferably, the information store 22 stores the information of connecting each conduit or conduit branch to a shutoff hole. Furthermore, the information store 22 preferably stores the information about connecting each room that has an indoor unit and/or that is crossed by at least one of the pipes to at least one shut-off valve. That is, the information store 22 stores the information shown in the Table 1 that links the unique identifiers of the sensor, space, pipe, and valve. In step S5, the identification portion 26 reads the identification number of the shut-off valve linked to the identification number of the identified leak detection sensor. This makes it possible to send a signal via a to the specific shut-off valves in fluid communication with the pipes crossing the area where the refrigerant leakage was detected. Therefore, in step S6, the signal output portion 29 sends out a signal for closing the identified shutoff valve(s). In slap 57, the shutoff valve(s) are closed upon receipt of the closing signal. In this way, any disturbance to the operation is of the air conditioning system due to refrigerant leakage is kept to an absolute minimum. As long as no leaks occur, normal operation of the system is maintained by a normal operation controller 28.

A first example is now given of the application of the method shown in flowchart 221 of Figure 5. In this example, the method is applied to the topology shown in Figure 4, where a refrigerant leak is detected by leak detection sensor a. In this example, the leak detection sensor a is located in room À that is crossed by pipe a.

This line is in fluid communication with shut-off valve W. Therefore, the signal

14 BE2022/5125 that is sent by leak detection sensor a to controller 16, ensure that said controller 16 sends a shut-off signal to shut-off valve W. In this case, only the first indoor unit 17 is switched off.

A second example is now given of the application of the method shown in flowchart 21 of Figure 5. In this example, the method is applied to the topology shown in Figure 4, where a refrigerant leak is detected by leak detection sensor f. In this example, the leak detection sensor F is located in room E, which is crossed by pipes à. These pipes are in fluid connection with shut-off valve Ÿ and shut-off valve Z.

Therefore, the signal sent by leak detection sensor f to controller 16 will cause the connected controller 16 to send a shut-off signal to shut-off valve Y and shut-off valve Z. In this case, only the third indoor unit 19 and fourth indoor unit 28 are turned off. A similar result would be obtained if a refrigerant leak were detected by sensor g or by both sensor f and sensor g.

A third example is now given of the application of the method shown in flowchart 21 of Figure 5. In this example, the method is applied to the topology shown in Figure 4, whereby a refrigerant leak is detected by leak detection sensor e. In this example, the leak detection sensor e is located in room D, which is crossed by pipes y and &. These pipes are in fluid connection with shut-off valve Y and shut-off valve Z.

Therefore, the signal sent by leak detection sensor e to controller 16 will cause said controller 16 to send a shut-off signal to shut-off valve Ÿ and shut-off valve Z. Although there are no indoor units in room D, the pipes y and & continue to room E , in which room the third indoor unit 19 and the fourth indoor unit 28 are located. Therefore, the third indoor unit 19 and fourth indoor unit 20 are switched off by closing the shut-off valve

Yen shut-off valve Z.

The present invention is by no means limited to the embodiments described in the examples and/or shown in the figures. On the contrary, methods according to the present invention can be realized in many different ways without departing from the scope of the invention.

List of numbered items 1 Air conditioning system 2 Compressor unit 5 3 switching unit

4 fan 5 first indoor unit 6 second indoor unit 7 third indoor unit

8 fourth indoor unit 9 fifth indoor unit 10 sixth indoor unit il seventh indoor unit 12 eighth indoor unit

13 ninth indoor unit 14 tenth indoor unit 15 second fan 16 controller 17 first indoor unit

18 second indoor unit 19 third indoor unit 20 fourth indoor unit 21 flowchart 22 information storage

23 information input 24 leakage management controller 25 leak detection section 26 identification section 27 memory read section

28 normal operation controller 29 signal output section 30 floor plan

Claims (13)

CONCLUSIONS 1. Air conditioning system, comprising: a compressor unit connected to multiple indoor units by means of multiple pipes; a switching unit between the compressor unit and each indoor unit, this switching unit comprising a plurality of shut-off valves connected to each pipe or pipe branch leading to an indoor unit; a multitude of leak detection sensors; and a controller configured to control the speed of shut-off valves and have information to associate each of the shut-off valves with at least one leak detection sensor; characterized in that the shut-off valve is operated on the basis of a signal from the coupled sensor. 2. Air conditioning system according to claim 1, characterized in that each room that has an indoor unit and/or that is crossed by at least one of the pipes is provided with at least one leak detection sensor. An air conditioning system according to claim 1 and claim 2, characterized in that the switching unit is a manifold configured to be connected to the compressor unit and to distribute a refrigerant input over multiple pipe branches. a. Air conditioning system according to claim 1 to claim 3, characterized in that the leak detection sensors are installed outside the indoor units. 5. Air conditioning system according to claim 1 to claim 4, characterized in that each leak detection sensor is linked to a room in which it is placed. &. Air conditioning system according to claim 1 to claim 5, characterized in that each pipe or pipe branch is coupled to a shut-off valve. 7. Air conditioning system according to claim 1 to claim 6, characterized in that each space that has an indoor unit and/or that is crossed by at least one of the pipes is connected to at least one shut-off valve. 8. Air conditioning system according to claim 1 to claim 7, characterized in that the switching unit is placed in a ventilated space. 9. Air conditioning system according to claim 1 to claim 8, characterized in that the compressor unit is placed in a ventilated space. Air conditioning system according to any one of claims 1 to 9, characterized in that each leak detection sensor is configured to close the shut-off valves associated with each room that has an indoor unit and/or that is crossed by at least one of the pipes , Air conditioning system according to any one of claims 1 to 10, characterized in that a refrigerant used in the air conditioning system is CO2 or R466A. 12. Method for establishing a control logic for operating the shut-off valves on the basis of a leak detection signal, comprising the steps of: registering leak detection sensors present in each room; registering pipes that run through or into each room; registering shut-off valves connected to each pipe; registering each leak detection sensor on at least one shut-off valve. 13. Method according to claim 12, characterized in that each sensor is registered with each shut-off valve that is linked to each pipe that runs through or in the space where the sensor is installed.