FR3112973A1 - System and method for disinfection of a hydraulic circuit - Google Patents

Abstract

The invention relates to a method and a system for disinfecting at least one hydraulic circuit HYC1, including means for injecting a cleaning fluid CFL into said circuit HYC1. According to the invention, this system includes hermetic sealing means MHF1 of the hydraulic circuit HYC1, intended to be implemented while said hydraulic circuit HYC1 is filled with cleaning fluid CFL. The MHF1 hermetic closure means prevent the entry and development in the HYC1 hydraulic circuit of foreign organisms, for example insects or bacteria, after the HYC1 hydraulic circuit has been drained using the injection means. Reference: Figure 1

Description

System and method for disinfection of a hydraulic circuit

The invention relates to a method and a system for disinfecting at least one hydraulic circuit, including means for injecting a cleaning fluid into said circuit.

The present invention falls within the field of the management and maintenance of seasonal, mobile or immovable dwellings, such as houses, mobile homes, camper vans or pleasure boats.

The invention is also applicable to the management and maintenance of hydraulic circuits including pipes that are not thermally insulated and therefore vulnerable to freezing, forming, for example, sanitary facilities in campsites or else irrigation or watering circuits for plantations. .

This invention aims more particularly to facilitate the emptying, disinfection and frost protection of plumbing circuits included in such installations, which are often left vacant or unused during certain parts of the year, and in particular during the winter season. .

The invention can also be implemented in the field of the agricultural industry, in particular for purifying water supply installations for livestock animals, since it does not require the use of any particular chemical product for its operation.

European patent EP 2 616 597 B1 describes a device for emptying a hydraulic circuit, which makes it possible to inject into said circuit a cleaning fluid consisting of water or air under pressure, with a view to rinsing and to empty said circuit before it is taken out of service, so as to avoid any bursting of one or more pipes under the effect of freezing.

The inventors have observed that, although the known device makes it possible to prevent a portion of the hydraulic circuit from remaining filled with water during its period of non-use, thus limiting the risks of bursting under the effect of freezing, it does not guarantee in any way the disappearance of any presence of water within the hydraulic circuit and therefore does not prevent the development within this circuit of any foreign organisms which could thrive in residual water reservoirs, for example insects or more bacteria such as that of legionellosis.

With a view to remedying the drawbacks stated above, the inventors propose an alternative solution taking the form of a method and a system for disinfecting at least one hydraulic circuit in accordance with the introductory paragraph, characterized in that it includes also means for sealing the hydraulic circuit, intended to be implemented while said circuit is filled with cleaning fluid.

The means of hermetic closure make it possible to prevent the entry and development of foreign organisms in the hydraulic circuit after it has been emptied, carried out using the injection means.

According to a first embodiment of the invention, the system described above includes an inlet valve provided with a first inlet connected to a water supply pipe, a second inlet connected to a inlet of pressurized cleaning fluid and an outlet connected to the hydraulic circuit via a non-return valve.

The implementation of such an inlet valve makes it possible to pass with great ease from a configuration of the hydraulic circuit to nominal operating mode, in which it is intended to receive water produced by the supply pipe. , to a drain configuration in which the circuit receives the cleaning fluid for cleaning and disinfection.

Furthermore, the non-return valve makes it possible to prevent, without any particular action being necessary for this purpose, a return of fluid from the hydraulic circuit to one or the other of the first and second inlets.

According to a second embodiment of the invention, which can advantageously be implemented cumulatively with the first embodiment described above, the inlet valve is provided with motorized switching means.

The implementation of motorized switching means within the inlet valve further facilitates the management of the system according to the invention, since it makes it possible to control the emptying operation in automatic form, and in particular at the means of an electrical command produced by a remotely configurable automaton.

According to a third embodiment of the invention, which can advantageously be implemented cumulatively with the first and second embodiments described above, the hermetic closure means include an exhaust valve connected to the hydraulic circuit and provided with motorized switching means.

The implementation of motorized switching means within the exhaust valve gives an additional degree of freedom to the management of the system according to the invention, since it makes it possible to control this exhaust valve in automatic form. , and in particular by means of an electrical command produced by a remotely configurable automaton. More specifically, this variant makes it possible to implement a delay in the opening of the exhaust valve with respect to the start of emptying command supplied to the inlet valve, so that the exhaust valve only opens for as short a time as possible to allow good evacuation of the cleaning fluid before the hermetic closure of the hydraulic circuit, which makes it possible to reduce as much as possible the risk of bacteria forming seep into the hydraulic circuit via the exhaust valve.

According to a particularly advantageous embodiment of the invention, the system described above further includes means for remote control of the motorized switching means included in the intake and exhaust valves.

The implementation of remote control means makes it possible to control the emptying, disinfection and closing operations without it being necessary for an operator to go on site to do this. Thus, multiple hydraulic circuits specific to different installations, such as for example a park of apartments, bungalows, mobile homes or motorhomes can be managed by means of a centralized control unit.

According to a preferred embodiment of the invention, the cleaning fluid is formed by ozone in the gaseous state.

Unlike other disinfection techniques, the use of ozone does not require the storage of hazardous products since it is produced directly on site and only when it is needed, a direct consequence of its instability. Furthermore, once the ozone has been imprisoned in the hydraulic circuit by the hermetic sealing means, there is no risk of it freezing in the presence of low temperatures, whereas water trapped in the hydraulic circuit would risk bursting the walls of the this one in case of prolonged frost.

According to a functional aspect, the invention also relates to a method for disinfecting at least one hydraulic circuit, including a step of injecting a cleaning fluid into said circuit,
method characterized in that it further includes a step of hermetically closing the hydraulic circuit, intended to be performed while said circuit is filled with cleaning fluid.

According to a variant of this functional aspect, the method as described above includes at least one step of remote control of motorized switching means included in intake and exhaust valves respectively connected to an inlet and to an outlet. of the hydraulic circuit.

Other characteristics and advantages of the invention will appear more clearly on reading the following description of particular embodiments, given by way of illustrative and non-limiting examples, and with regard to the appended drawings, among which:

Fig.1

is a functional diagram of a disinfection system of a hydraulic circuit according to a particular embodiment of the invention; And

Fig.2

is a functional diagram of a management and maintenance system for a plurality of disinfection systems in accordance with a particularly advantageous embodiment of the invention.

FIG. 1 represents in functional form a system SYST1 for disinfection of at least one hydraulic circuit HYC1 included in a seasonal dwelling, which in this example is a mobile home.

1. Les moyens de fermeture hermétique MHF1 permettent de prévenir l’entrée et le développement dans le circuit hydraulique HYC1 d’organismes étrangers, par exemple des insectes ou encore des bactéries, après vidange dudit circuit hydraulique HYC1 grâce aux moyens d’injection.

In accordance with the invention, this disinfection system SYST1 includes, in addition to means for injecting a cleaning fluid CFL into said circuit HYC1, means for hermetically closing MHF1 of the hydraulic circuit HYC1, intended to be implemented while said hydraulic circuit HYC1 is filled with cleaning fluid CFL.

1. The hermetic closure means MHF1 make it possible to prevent the entry and development in the hydraulic circuit HYC1 of foreign organisms, for example insects or even bacteria, after said hydraulic circuit HYC1 has been drained by means of the injection means.

In the embodiment of the invention represented here, the cleaning fluid CFL is formed by ozone in the gaseous state, produced by an ozone generator GCNT1 and intended to be injected into the hydraulic circuit HYC1 by means of a pump PMP1 controlled by means of a pump control signal PCNT1.

Unlike other disinfection techniques, the use of ozone does not require the storage of hazardous products since it is produced directly on site by the OZG1 generator and only after reception of a GCNT1 production control signal. Furthermore, once the ozone has been trapped in the hydraulic circuit HYC1 by the hermetic closure means MHF1, there is no risk of it freezing in the presence of low temperatures, whereas water trapped in the hydraulic circuit HYC1 could cause the its walls in the event of prolonged frost.

In this embodiment of the invention, the system SYS1 includes an inlet valve IV1 provided with a first inlet connected to a water supply pipe OE1, a second inlet connected to an inlet pipe of cleaning fluid CFL under pressure and an outlet connected to the hydraulic circuit HYC1 via a non-return valve not shown here.

The implementation of such an inlet valve IV1 makes it possible to pass with great ease from a configuration of the hydraulic circuit HYC1 to nominal operating mode, in which it is intended to receive water produced by the pipeline of water supply OE1, to a drain configuration in which the circuit receives the cleaning fluid CFL with a view to its cleaning and disinfection, the non-return valve making it possible to prevent, without any particular action is necessary for this purpose, a return of fluid from the hydraulic circuit HYC1 to one or the other of the first and second inlets.

In the embodiment of the invention described here, the inlet valve IV1 is provided with motorized switching means ICM1 which make it possible to control the emptying operation in automatic form, and in particular by means of a signal admission control ICNT1 produced by a remotely configurable control automaton CBX1, which automaton CBX1 can also produce the production control signal GCNT1 of the ozone generator OZG1.

In this embodiment of the invention, the hermetic closure means MHF1 include an exhaust valve OV1 connected to the hydraulic circuit HYC1 and provided with motorized switching means OCM1, which make it possible to control this exhaust valve OV1 under automatic form, and in particular by means of an escape control signal OCNT1 produced by the control automaton CBX1. More specifically, this variant makes it possible to implement a time delay for the opening of the exhaust valve OV1 with respect to the start of emptying command supplied to the inlet valve IV1, so as to that the exhaust valve OV1 only opens for as short a time as possible to allow good evacuation of the cleaning fluid CFL before the hermetic closing of the hydraulic circuit HYC, which makes it possible to reduce as much as possible the risk for that insects and/or bacteria infiltrate the hydraulic circuit HYC via the exhaust valve OV1.

Advantageously, the SYST1 system will include remote control means for the motorized switching means included in the ICM1 intake and OCM1 exhaust valves. Such remote control means will be made in part by wired connections between the CBX1 control automaton and the ICM1 inlet and OCM1 exhaust valves, and in part by radio wave reception means with which said controller CBX1, for example a Wi-Fi communication module.

In a particularly advantageous manner, the radio wave reception means fitted to the CBX1 control automaton will also be able to receive control instructions from the ozone generator OZG1 and from the pump PMP1 which is associated with it.

The implementation of remote control means makes it possible to control the emptying, disinfection and closing operations of the HYC1 hydraulic circuit without it being necessary for an operator to go on site to do this. Thus, multiple hydraulic circuits specific to different installations, such as for example a park of apartments, bungalows, mobile homes or motorhomes can be managed by means of a centralized control unit, as will be explained. below.

FIG. 2 represents in functional form a system for managing and maintaining a plurality of disinfection systems (SYST1, SYST2, SYST3…SYSTK) in accordance with a particularly advantageous embodiment of the invention.

This type of system can be present in collective seasonal housing installations, for example on a campsite or in a marina.

In the system shown here, a centralized CNC control entity is equipped with telecommunication means to exchange information with control automatons (CBX1, CBX2, CBX3…CBXK) specific to the different disinfection systems (SYST1, SYST2, SYST3…SYSTK ) intended to be controlled remotely by the CNC centralized control entity. These means of telecommunication could for example consist of a Wi-Fi communication module with which each of the control automata (CBX1, CBX2, CBX3…CBXK) will also be equipped.

The CNC centralized control entity may be constituted by a fixed control console such as a computer, but also by a mobile control terminal such as a smartphone equipped with a specific software application.

This CNC control entity is intended to send control instructions (CSG1, CSG2, CSG3… CSGK) allowing said automaton (CBXi, for i=1 to K) to produce the command and control signals for the intake and exhaust valves (ICNTi and OCNTi, for i=1 to K), as well as the production and pumping control signals (GCNTi and PCNTi, for i=1 to K) of the cleaning fluid.

In the particular embodiment represented here, the telecommunication means with which the CNC control entity is equipped are able to receive from each of the control automata (CBX1, CBX2, CBX3…CBXK) information feedback signals (RI1 , RI2, RI3…RIK) allowing each of the control automatons (CBX1, CBX2, CBX3…CBXK) to report on the operations in progress within the disinfection system (SYST1, SYST2, SYST3…SYSTK) that it controls, in order to allow an operator of the CNC control entity to adjust certain parameters specific to these operations, such as, for example, delay times between the opening of an inlet valve and the closing of an an exhaust valve, or even the duration of production and/or pumping of ozone within one or more disinfection systems in use.

Claims (8)

Disinfection system for at least one hydraulic circuit (HYC1), including means for injecting a cleaning fluid (CFL) into said circuit (HYC1),
system characterized in that it further includes hermetic closing means (MHF1) of the hydraulic circuit (HYC1), intended to be implemented while said hydraulic circuit (HYC1) is filled with cleaning fluid (CFL). System according to claim 1, characterized in that it includes an inlet valve (IV1) provided with a first inlet connected to a water supply pipe (OE1), a second inlet connected to a water supply pipe arrival of pressurized cleaning fluid (CFL), and an outlet connected to the hydraulic circuit (HYC1) via a non-return valve. System according to Claim 2, characterized in that the inlet valve (MOV1) is provided with motorized switching means (ICM1). System according to Claim 3, characterized in that the hermetic closing means (MHF1) include an exhaust valve (EV1) connected to the hydraulic circuit (HYC1) and provided with motorized switching means (OCM1). System according to Claim 4, characterized in that it also includes remote control means (CNC) of the motorized switching means (ICM1, OCM1) included in the intake and exhaust valves. System according to one of Claims 1 to 5, characterized in that the cleaning fluid (CFL) is formed by ozone in the gaseous state. Method for disinfecting at least one hydraulic circuit (HYC1), including a step of injecting a cleaning fluid (CFL) into said circuit (HYC1),
method characterized in that it further includes a step of hermetically closing the hydraulic circuit (HYC1), intended to be performed while said circuit (HYC1) is filled with cleaning fluid (CFL). Disinfection method according to Claim 7, characterized in that it includes at least one step of remote control of motorized switching means (ICM1, OCM1) included in the inlet and outlet valves (IV1, OV1) respectively connected to an inlet and an outlet of the hydraulic circuit (HYC1).