EP3682216B1 - Hydraulic integrator and method for centralised management of the hydraulic network of a plant - Google Patents

Description

The present invention relates to the field of methods and systems for distributing water in installations. In particular, reference will be made to a method and a system allowing centralized management of a hydraulic network of one or more installations. The present invention thus relates to a hydraulic integrator intended to simplify the layout of a hydraulic network of an installation. The invention also relates to methods of centralized management of a hydraulic network capable of implementing said hydraulic integrator.

[Prior art]

The hydraulic network of an installation generally comprises a set of tubes linked to the distribution of cold water and a set of tubes linked to the distribution of hot water. These sets allow water to be transported to sanitary devices such as sinks, bathtubs, showers, etc. or also household appliances such as dishwashers and washing machines.

The installation of the hydraulic network of new installations such as housing, offices or buildings requires the shaping of pipes or pipes and must be done in accordance with established regulations (e.g. in France NF DTU 60.1). The shaping of pipes generally consists of cutting, threading, bending and / or drilling the tubes. These operations are generally carried out on the site of the installations intended to receive the hydraulic networks. The next step is the realization of the assembly of the shaped elements. This assembly, depending on the nature of the pipes, can be done by screwing, brazing, autogenous welding, capillary brazing, compression fitting, special fittings, crimp fittings, flanges or tapping. Likewise, the pipes are fixed independently against the walls of the installation using brackets or metal clamps depending on the nature of the pipes. This independent installation of the different portions of pipes is very time-consuming.

Thus, all these steps consume time and potentially generate accidents. This is all the more the case at the central distribution point of the hydraulic network, when connecting these sets of tubes to the main sources of cold water on the one hand and hot water on the other hand. Indeed, it is at the level of these connections that the job is the most time consuming and potential source of accident. In addition, when making these connections, tightenings whose force is not properly applied can damage the water distribution point.

In addition, existing systems make it possible to control the hydraulic network of an installation from sensors distributed throughout the installation. Current systems are generally based on monitoring different points of a water supply network with an increase in the number of these distributed devices. Thus, there are several systems such as those described in the document FR2922015 which are based on the installation of a plurality of sensors in each room with a centralization of information. However, these sensors and / or actuators generally require the establishment of wireless communication to allow communication of the sensors-actuators with the central monitoring and control unit. In the absence of wireless communication, it requires the installation of a whole network of distributed cabling in the installation. In addition, this type of decentralized distribution has drawbacks such as the installation time which represents many hours to install distributed monitoring devices in each of the rooms and the cost associated with this installation and its maintenance.

The document US2016 / 161940 proposes, for example, an intelligent system capable of storing information on the consumption habits of a user using sensors, and capable of alerting a user using wireless communication. The document US2012 / 291886 meanwhile, it also offers a remote control system for the water supply of a building using sensors detecting a lack of water and a control unit making it possible to communicate with a remote device. However, these systems require significant installation time as well as effort during the installation and set-up of the system. To overcome installation difficulties, there are devices for fixing or connecting water supply pipes to a wall structure to facilitate the connections between secondary pipes and supply lines as illustrated in the document. US2012 / 273064 . It has also been detailed mounting brackets allowing on the one hand to fix different pipes and on the other hand allowing their correct positioning as explained in the document. US2015 / 204461 . However, these arrangement and fixing means facilitate installation only for the connection between pipes, which can therefore leave room for poor workmanship during complex installation comprising the connection of numerous main and secondary pipes. In addition, there are still difficulties for the complete installation of a centralized water distribution system and its fitting out in an installation.

Finally, in some countries, tap water is one of the most controlled foods, subject to permanent monitoring, intended to guarantee its sanitary safety. However, such control is not systematic in all countries and a lack of maintenance of catchment structures, a failure of the disinfection treatment or contamination of the water during its transport or storage in the network can lead to distribution in the installation of potentially unsanitary water. Indeed, the presence of microorganisms in drinking water can create a short-term risk for the consumer. Likewise, certain water supplies may contain excessively high concentrations of lead or nitrates. In the human body, nitrates are converted into nitrites. These can present a risk to health, especially pregnant women and infants, by altering the properties of hemoglobin in the blood by preventing proper transport of oxygen by red blood cells. Other organic compounds (or organic load), such as pesticides or emerging substances (e.g. drug residues, hormones) can also be found in certain water networks.

Thus, there is a need for new devices allowing the installation of a rapid hydraulic network, with reduced risks of accidents and poor workmanship and making it possible to facilitate the maintenance of the devices for controlling the water distribution and reduce costs as well as health risks.

[Technical problem]

The aim of the invention is therefore to remedy the drawbacks of the prior art. In particular, the invention aims to provide a hydraulic integrator, also called a concentrator, capable of responding to the problems associated with construction costs and the risks associated with shaping the central point of the hydraulic network on the site.

The object of the invention is also to respond to the problems caused by distributed monitoring systems and therefore to respond to the cumbersome associated with the on-site configuration of existing distributed systems. The invention also responds to the maintenance problems of distributed control systems in installations requiring the different control devices to be found within the installation.

Another object of the invention is to propose a method for managing water consumption allowing consumption to be controlled while offering increased comfort.

[Brief description of the invention]

• au moins un collecteur sanitaire eau froide apte à distribuer de l'eau froide, comportant plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• au moins un collecteur sanitaire eau chaude, apte à distribuer de l'eau chaude, comportant au moins une sonde de température et plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• une unité de commande apte à recevoir des informations de débitmètres et de sonde de température et apte à contrôler l'ensemble des électrovannes ; et
• un support sur lequel sont fixés l'unité de commande et les collecteurs sanitaire eau froide et eau chaude, ledit support étant destiné à être fixé contre l'un des murs de l'installation.

To this end, the invention relates to a hydraulic integrator for the centralized management of a hydraulic network of one or more installations, characterized in that it comprises:

• at least one sanitary cold water collector capable of distributing cold water, comprising several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• at least one domestic hot water manifold, capable of distributing hot water, comprising at least one temperature sensor and several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• a control unit able to receive information from flowmeters and temperature probe and able to control all of the solenoid valves; and
• a support on which the control unit and the hot and cold water sanitary collectors are fixed, said support being intended to be fixed against one of the walls of the installation.

Advantageously, said integrator is in prefabricated form. Such a hydraulic integrator, given that it comprises valves and a cold water collector and a hot water collector fixed on a support, can then be quickly installed on the installation site and save significant time. and reduced risk of accidents. This is possible because a majority of the design operations for the conduits or tubes required at the central distribution point have been carried out before installation on site.

It constitutes a solution allowing, from a single location of the installation, to control all the water inflows to the sanitary devices of the installation and its configuration is fast because at the time of manufacture it may already be known to which equipment will be directed to each of the distribution outlets of the collectors. Finally, it is not concerned by the redevelopment issues that systems distributed in a dwelling could face. It also has a small footprint and low maintenance.

• le collecteur sanitaire eau chaude comporte au moins deux sondes de température. De façon préférée, il est équipé à chacune de ses deux extrémités d'une sonde de température et d'un moyen de raccordement apte à permettre un raccordement amovible à un moyen de production d'eau chaude. Cela confère à l'intégrateur hydraulique une forte versatilité lui permettant d'être facilement relié au moyen de production d'eau chaude. En outre, la présence de deux sondes de température permet de réduire le risque de développement de légionnelles dans l'installation étant donné que cela permet de rapidement identifier une température trop faible, propice au développement des légionnelles.
• l'intégrateur hydraulique comporte en outre un collecteur eau récupérée apte à distribuer de l'eau collectée, comportant plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne. La présence du collecteur eau récupérée dans l'intégrateur hydraulique permet d'ajouter ponctuellement ou en continue dans le réseau hydraulique une eau collectée, moins précieuse que de l'eau potable, sans que cela ne nuise à la qualité globale du service. En effet, pour certains équipements tels que des toilettes, si de l'eau collectée est disponible, alors il est préférable que l'eau potable soit remplacée par cette eau collectée et cela sans avoir à intervenir manuellement sur l'installation. Ainsi, avantageusement, le collecteur eau collectée est relié à un moyen de stockage d'eau récupérée et l'unité de commande est apte à recevoir une information sur le volume d'eau collectée présent dans le moyen de stockage d'eau collectée.
• l'au moins un collecteur sanitaire eau froide est équipé à l'extrémité aval de chacune des sorties de distribution d'un moyen de raccordement apte à permettre un raccordement amovible. Cela facilite l'installation sur site de l'intégrateur hydraulique.
• les extrémités de l'au moins un collecteur sanitaire eau froide sont avantageusement positionnées au niveau d'un bord du support. Ceci de façon à faciliter leur jonction avec une arrivée d'eau.
• l'au moins un collecteur sanitaire eau froide comporte au moins une sonde de température. Une telle sonde peut permettre une fonction d'alerte de branchement sur bouclage par l'unité de commande. Cela permet également un suivi du risque de gel dans une installation, l'intégrateur hydraulique alors configuré pour transmettre une alerte à un utilisateur en cas de température trop basse (e.g. inférieur à 5°C ou 2°C) et si nécessaire proposer la mise en place de mesures préventives.
• les débitmètres, sondes de température et électrovannes sont reliés à l'unité de commande de façon filaire. Ceci permettant une réduction importante des coûts.
• l'intégrateur hydraulique comporte en outre un régulateur de pression, de préférence positionné en amont du collecteur sanitaire eau froide. La présence de ce régulateur de pression en entrée permet notamment de contrecarrer l'augmentation de pression la nuit ou sur les périodes estivales et ainsi réduire significativement la consommation d'eau par l'installation.
• l'intégrateur hydraulique comprend en outre un module de communication et un moyen de stockage de données. Cela permet à l'intégrateur hydraulique de proposer des services à haute valeur ajoutée tels que des procédés de surveillance de la consommation en eau, de priorisation des équipements, d'alertes ou encore de réduction de la consommation.
• le support comporte au moins une plaque en matériau polymère rigide. Avantageusement, le support comporte au moins une plaque en matériau polymère rigide d'une densité supérieure à 800 kg/m³, de préférence d'une densité supérieure à 1000 kg/m³, de façon plus préférée d'une densité supérieure à 1200 kg/m³. Cela permet de disposer d'un intégrateur hydraulique dont le support est résistant à la déformation.
• il comporte au moins un moyen de contrôle de la qualité de l'eau, de préférence sélectionné parmi : conductimètre, pH-mètre, oxymètre, turbimètre, sonde de mesure des nitrates, et sonde de mesure de charge organique. Un tel moyen de contrôle de la qualité de l'eau permet de garantir la sécurité sanitaire des utilisateurs par exemple dans le cas de contaminations de l'eau par des microorganismes pathogènes, du plomb, des nitrates ou d'autres substances organiques potentiellement néfastes. En effet, un tel moyen de contrôle est généralement utilisé dans un procédé de surveillance en temps réel et en continue pour la qualité de l'eau.
• l'intégrateur comporte au moins un capteur dit d'ambiance sélectionné parmi un capteur de température, un capteur d'humidité, un baromètre, un capteur de dioxyde de carbone, un capteur de monoxyde de carbone et un capteur de composés organiques volatiles. Ainsi, l'intégrateur hydraulique pourra générer des alertes à destination de l'utilisateur en cas de dégradation de la qualité d'air du logement ou bien adapter la gestion de l'eau à la présence ou l'absence des utilisateurs dans le logement.
• chacune des sorties de distribution est reliée à un moyen de raccordement apte à permettre un raccordement amovible, ledit moyen de raccordement présente une section transversale ayant une forme géométrique n'étant pas circulaire et ledit intégrateur hydraulique comporte un moyen de maintien comportant une ou plusieurs ouvertures dont la forme est sensiblement identique à la forme de la section transversale dudit moyen de raccordement. Cela permet de supprimer les risques d'endommagement de l'intégrateur hydraulique liés à des serrages dont la force n'est pas convenablement appliquée lors de ces raccordements car le moyen de maintien empêche que la force de torsion ne soit transmise aux composants de l'intégrateur (e.g. débitmètre, électrovanne...).
• il comporte un module de communication configuré pour recevoir et transmettre des données à une enceinte comportant un microphone et un haut-parleur.
• il peut être utilisé en association avec un ou plusieurs intégrateurs hydrauliques auxiliaires et l'unité de commande est apte à recevoir, de ces intégrateurs hydrauliques auxiliaires, les informations de débitmètres et de sonde de température et apte à contrôler les électrovannes de ces un ou plusieurs intégrateurs hydrauliques auxiliaires. L'intégrateur hydraulique selon l'invention est alors configuré pour jouer le rôle de superviseur du fonctionnement des intégrateurs hydrauliques auxiliaires.

According to other optional characteristics of the hydraulic integrator:

• the domestic hot water manifold has at least two temperature probes. Preferably, it is equipped at each of its two ends with a temperature probe and a connection means capable of allowing a removable connection to a means. hot water production. This gives the hydraulic integrator great versatility allowing it to be easily connected to the means of hot water production. In addition, the presence of two temperature probes makes it possible to reduce the risk of Legionella developing in the installation, since this makes it possible to quickly identify a temperature that is too low, favorable to the development of Legionella.
• the hydraulic integrator further comprises a recovered water manifold capable of distributing collected water, comprising several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve. The presence of the collected water collector in the hydraulic integrator makes it possible to occasionally or continuously add collected water to the hydraulic network, which is less valuable than drinking water, without this affecting the overall quality of the service. Indeed, for certain equipment such as toilets, if collected water is available, then it is preferable that drinking water be replaced by this collected water and that without having to intervene manually on the installation. Thus, advantageously, the collected water collector is connected to a means for storing recovered water and the control unit is able to receive information on the volume of collected water present in the means for storing collected water.
• the at least one sanitary cold water collector is equipped at the downstream end of each of the distribution outlets with a connection means capable of allowing a removable connection. This facilitates the on-site installation of the hydraulic integrator.
• the ends of the at least one sanitary cold water collector are advantageously positioned at an edge of the support. This in order to facilitate their junction with a water inlet.
• the at least one sanitary cold water collector comprises at least one temperature sensor. Such a probe can allow a looping connection alert function by the control unit. This also allows monitoring of the risk of freezing in an installation, the hydraulic integrator then configured to send an alert to a user in the event of the temperature being too low (eg less than 5 ° C or 2 ° C) and if necessary propose the setting. in place of preventive measures.
• flowmeters, temperature sensors and solenoid valves are wired to the control unit. This allows a significant reduction in costs.
• the hydraulic integrator further comprises a pressure regulator, preferably positioned upstream of the domestic cold water manifold. The presence of this inlet pressure regulator makes it possible in particular to counteract the increase in pressure at night or during the summer periods and thus significantly reduce the water consumption by the installation.
• the hydraulic integrator further comprises a communication module and a data storage means. This allows the hydraulic integrator to offer high added value services such as water consumption monitoring processes, equipment prioritization, alerts or even consumption reduction.
• the support comprises at least one plate of rigid polymer material. Advantageously, the support comprises at least one plate of rigid polymer material with a density greater than 800 kg / m ³ , preferably a density greater than 1000 kg / m ³ , more preferably a density greater than 1200. kg / m ³ . This makes it possible to have a hydraulic integrator whose support is resistant to deformation.
• it comprises at least one water quality control means, preferably selected from: conductivity meter, pH meter, oximeter, turbimeter, nitrate measurement probe, and organic load measurement probe. Such a means of controlling the quality of the water makes it possible to guarantee the health safety of the users, for example in the case of contamination of the water by pathogenic microorganisms, lead, nitrates or other potentially harmful organic substances. Indeed, such a control means is generally used in a real-time and continuous monitoring process for the quality of the water.
• the integrator comprises at least one so-called ambient sensor selected from among a temperature sensor, a humidity sensor, a barometer, a carbon dioxide sensor, a carbon monoxide sensor and a volatile organic compound sensor. Thus, the hydraulic integrator will be able to generate alerts for the user in the event of a deterioration in the air quality of the home or adapt water management to the presence or absence of users in the home.
• each of the distribution outlets is connected to a connection means capable of allowing a removable connection, said connection means has a cross section having a geometric shape that is not circular and said hydraulic integrator comprises a holding means comprising one or more openings the shape of which is substantially identical to the shape of the cross section of said connecting means. This eliminates the risk of damage to the hydraulic integrator associated with tightening the force of which is not properly applied during these connections because the retaining means prevents the torsional force from being transmitted to the components of the integrator (eg flowmeter, solenoid valve, etc.).
• it comprises a communication module configured to receive and transmit data to an enclosure comprising a microphone and a speaker.
• it can be used in association with one or more auxiliary hydraulic integrators and the control unit is able to receive, from these auxiliary hydraulic integrators, flowmeter and temperature sensor information and able to control the solenoid valves of these one or more auxiliary hydraulic integrators. The hydraulic integrator according to the invention is then configured to play the role of supervisor of the operation of the auxiliary hydraulic integrators.

According to another aspect, the invention relates to a system for centralized management of the water supply to a hydraulic network of one or more installations comprising a hydraulic integrator according to the invention and at least one auxiliary hydraulic integrator. This is particularly advantageous in the case of building a hotel or a nursing home with a plurality of rooms or individual facilities.

• un collecteur sanitaire eau froide, apte à la gestion de la distribution d'eau froide, comportant plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• un collecteur sanitaire eau chaude, apte à la gestion de la distribution d'eau chaude, comportant au moins deux sondes de température et plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ; et
• un support sur lequel sont fixés les collecteurs sanitaires eau froide et eau chaude, ledit support étant destiné à être fixé contre l'un des murs de l'installation.

According to other optional features, the centralized management system of the water supply to a hydraulic network of one or more installations comprising at least one integrator according to the invention fluidly coupled to an extension, said extension comprising:

• a cold water sanitary manifold, suitable for managing the distribution of cold water, comprising several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• a domestic hot water manifold, suitable for managing the distribution of hot water, comprising at least two temperature probes and several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve; and
• a support on which the cold water and hot water sanitary collectors are fixed, said support being intended to be fixed against one of the walls of the installation.

Such an extension makes it possible to multiply the number of outlets of the hydraulic integrator or to add the possibility of managing other water networks such as rainwater or treated gray water.

According to another aspect, the invention relates to a method for managing the centralization of the water supply to a hydraulic network of one or more installations implementing the hydraulic integrator according to the invention, said method comprising a recording step during which flow rate information, generated by flow meters, and / or temperature information, generated by temperature probes, are recorded on a data storage means. Thus, the hydraulic integrator can be able to anticipate the user's needs and help him control his water consumption. The The following functions relate to the contextualization of water consumption in the building and are based on memorizing past consumption or reference consumption associated with recommendations issued by the system.

• Définition d'un groupe d'équipements où chaque équipement est relié à au moins une sortie de distribution d'un même collecteur sanitaire,
• Définition d'une valeur de débit total critique pour ledit groupe d'équipements,
• Définition, au sein du groupe d'équipements, d'un ou plusieurs équipements non prioritaires,
• Acquisition par l'unité de commande des valeurs de débit, transmises par les débitmètres, pour chacune des sorties de distribution reliées aux équipements dudit groupe d'équipements,
• Comparaison de la somme des valeurs de débit des équipements du groupe d'équipements à la valeur de débit total critique pour ledit groupe d'équipements,
• Génération, si la somme des valeurs de débit des équipements du groupe d'équipements dépasse la valeur de débit total critique pour ledit groupe d'équipements, d'une instruction de réduction du débit aux électrovannes associées aux sorties de distribution reliées aux équipements non prioritaire dudit groupe d'équipements.

For example, the invention relates to a method, or a step, of equipment prioritization, said equipment prioritization comprising the following steps:

• Definition of a group of equipment where each equipment is connected to at least one distribution outlet of the same sanitary manifold,
• Definition of a critical total flow value for said group of equipment,
• Definition, within the group of equipment, of one or more non-priority equipment,
• Acquisition by the control unit of the flow values, transmitted by the flow meters, for each of the distribution outputs connected to the equipment of said group of equipment,
• Comparison of the sum of the throughput values of the devices of the group of devices with the critical total flow value for said group of devices,
• Generation, if the sum of the flow values of the devices of the group of devices exceeds the critical total flow value for said group of devices, of an instruction to reduce the flow to the solenoid valves associated with the distribution outputs connected to the non-priority devices of said group of equipment.

• Définition d'un groupe d'équipement eau collectée où chaque équipement est apte à utiliser de l'eau collectée et est relié à une sortie de distribution d'un collecteur eau récupérée,
• Définition d'une valeur minimale de volume d'eau collectée,
• Acquisition, par l'unité de commande, d'une valeur de volume actuel d'eau collectée présent dans un moyen de stockage d'eau collectée,
• Comparaison de la valeur de volume actuel d'eau collectée à la valeur minimale de volume d'eau collectée, et
• Génération, si la valeur de volume actuel d'eau collectée dépasse la valeur minimale de volume d'eau collectée, d'une instruction d'ouverture des électrovannes positionnées sur les sorties de distribution, du collecteur eau récupérée, reliées aux équipements appartenant au groupe d'équipement eau collectée.

The invention relates to a method or a step for managing collected water, said managing collected water comprising the following steps:

• Definition of a group of collected water equipment where each equipment is able to use collected water and is connected to a distribution outlet of a collected water collector,
• Definition of a minimum value for the volume of water collected,
• Acquisition, by the control unit, of a current volume value of collected water present in a collected water storage means,
• Comparison of the current volume value of collected water to the minimum value of collected water volume, and
• Generation, if the current volume value of collected water exceeds the minimum value of collected water volume, of an instruction to open the solenoid valves positioned on the distribution outlets, of the recovered water collector, connected to the equipment belonging to the group water collection equipment.

• Définition d'au moins une valeur standard de consommation d'eau en fonction du temps pour ladite installation,
• Acquisition, par l'unité de commande, d'une valeur actuelle de débit pour chaque sortie de distribution des collecteurs sanitaire, avec de préférence un enregistrement sur un moyen de stockage de données,
• Traitement des valeurs actuelles de débit de façon à obtenir une valeur actuelle de consommation en eau en fonction du temps,
• Comparaison de la valeur actuelle de consommation en eau à la valeur standard de consommation d'eau pour une même période de temps, et
• Génération, si la valeur actuelle de consommation en eau dépasse la valeur standard de consommation d'eau pour une même période de temps, d'une alerte de consommation inhabituelle.

The invention relates to a method, or a step, of monitoring the water network, said monitoring of the water network comprising the following steps:

• Definition of at least one standard value of water consumption as a function of time for said installation,
• Acquisition, by the control unit, of a current flow rate for each distribution outlet of the sanitary manifolds, preferably with a recording on a data storage means,
• Treatment of the current flow values so as to obtain a current value of water consumption as a function of time,
• Comparison of the current value of water consumption to the standard value of water consumption for the same period of time, and
• Generation, if the current water consumption value exceeds the standard water consumption value for the same period of time, of an unusual consumption alert.

• Identifier une consommation inhabituelle en eau,
• Mesurer une concentration en dioxyde de carbone dans l'air de l'installation,
• Comparer, par l'unité de commande, la concentration en dioxyde de carbone mesurée à des concentrations en dioxyde de carbone prédéterminées, de préférence pour la période donnée ou pour une période équivalente, et
• Générer, par l'unité de commande, une alerte si la concentration en dioxyde de carbone dans l'air de l'installation est sensiblement égale à la concentration en dioxyde de carbone prédéterminée

L'identification de la consommation inhabituelle peut par exemple être basée sur le procédé de surveillance selon l'invention.The invention also relates to a method for correlating consumption with occupancy, said correlation step comprising the following steps:

• Identify unusual water consumption,
• Measure a carbon dioxide concentration in the air of the installation,
• Compare, by the control unit, the measured carbon dioxide concentration with predetermined carbon dioxide concentrations, preferably for the given period or for an equivalent period, and
• Generate, by the control unit, an alert if the carbon dioxide concentration in the air of the installation is approximately equal to the predetermined carbon dioxide concentration

The identification of unusual consumption can for example be based on the monitoring method according to the invention.

• Définition d'une valeur minimale et/ou maximale d'un paramètre relatif à la qualité de l'eau sur le réseau,
• Acquisition par l'unité de commande, d'une valeur de paramètre relatif à la qualité de l'eau sur le réseau, mesurée par un moyen de contrôle de la qualité de l'eau,
• Comparaison par l'unité de commande, de la valeur actuelle du paramètre relatif à la qualité de l'eau aux valeurs minimale et/ou maximale définies, et
• Génération par l'unité de commande, si la valeur actuelle de pression du paramètre relatif à la qualité de l'eau indique une dégradation de la qualité de l'eau, d'une instruction de fermeture d'électrovannes.

The invention also relates to a method for controlling the quality of water on a hydraulic network comprising the following sub-steps:

• Definition of a minimum and / or maximum value of a parameter relating to the quality of the water on the network,
• Acquisition by the control unit of a parameter value relating to the quality of the water on the network, measured by a water quality control means,
• Comparison by the control unit of the current value of the water quality parameter with the defined minimum and / or maximum values, and
• Generation by the control unit, if the current pressure value of the parameter relating to the water quality indicates a degradation of the water quality, of an instruction to close solenoid valves.

• Acquisition, par l'unité de commande, d'une valeur de mesurée de consommation d'eau par un équipement non sanitaire,
• Comparaison de la valeur de consommation d'eau par un équipement non sanitaire à une valeur de consommation d'eau prédéterminée, et
• Génération, par l'unité de commande, si la consommation mesurée dépasse la valeur de consommation d'eau prédéterminée, d'une instruction d'alerte de consommation inhabituelle et/ou de fermeture d'une vanne associée audit équipement non sanitaire.

The invention also relates to a method of managing non-sanitary equipment comprising the following steps:

• Acquisition, by the control unit, of a measured value of water consumption by non-sanitary equipment,
• Comparison of the water consumption value by non-sanitary equipment with a predetermined water consumption value, and
• Generation, by the control unit, if the measured consumption exceeds the predetermined water consumption value, of an unusual consumption alert instruction and / or closing of a valve associated with said non-sanitary equipment.

• Figure 1, un schéma de l'organisation d'un intégrateur hydraulique selon un mode de réalisation de l'invention.
• Figures 2A et 2B, deux schémas de l'organisation d'un intégrateur hydraulique selon d'autre modes de réalisation de l'invention et notamment dans le cadre d'un système de gestion hydraulique centralisée.
• Figures 3A et 3B, un support de l'intégrateur hydraulique selon un mode de réalisation de l'invention (A), et une vue en perspective du support de l'intégrateur hydraulique selon un autre mode de réalisation de l'invention (B).
• Figure 4, une vue en perspective d'un moyen de maintien selon l'invention.
• Figure 5, une représentation schématique d'un procédé de suivi de température de l'eau sur le réseau hydraulique selon l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 6, une représentation schématique d'un procédé, ou d'une étape, de priorisation d'équipement selon l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 7, une représentation schématique d'un procédé, ou d'une étape, de gestion d'eau collectée selon un mode de réalisation de l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 8, une représentation schématique d'un procédé, ou d'une étape, de régulation de la pression sur le réseau hydraulique selon l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 9, une représentation schématique d'un procédé, ou d'une étape, de surveillance du réseau hydraulique selon l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 10, une représentation schématique d'un procédé selon l'invention de corrélation de la consommation à l'occupation de l'installation.
• Figure 11, une représentation schématique d'un procédé de contrôle de la qualité de l'eau sur le réseau hydraulique selon l'invention. Les étapes représentées en pointillées sont facultatives.
• Figure 12, une représentation schématique d'un procédé de gestion d'équipements non sanitaires selon l'invention. Les étapes représentées en pointillées sont facultatives.

Other advantages and characteristics of the invention will become apparent on reading the following description given by way of illustrative and non-limiting example, with reference to the appended figures which represent:

• Figure 1 , a diagram of the organization of a hydraulic integrator according to one embodiment of the invention.
• Figures 2A and 2B , two diagrams of the organization of a hydraulic integrator according to other embodiments of the invention and in particular in the context of a centralized hydraulic management system.
• Figures 3A and 3B , a support for the hydraulic integrator according to one embodiment of the invention (A), and a perspective view of the support for the hydraulic integrator according to another embodiment of the invention (B).
• Figure 4 , a perspective view of a holding means according to the invention.
• Figure 5 , a schematic representation of a method for monitoring the temperature of the water on the hydraulic network according to the invention. Steps shown in dotted lines are optional.
• Figure 6 , a schematic representation of a method, or of a step, for prioritizing equipment according to the invention. Steps shown in dotted lines are optional.
• Figure 7 , a schematic representation of a method, or of a step, for managing collected water according to one embodiment of the invention. Steps shown in dotted lines are optional.
• Figure 8 , a schematic representation of a method, or of a step, for regulating the pressure on the hydraulic network according to the invention. Steps shown in dotted lines are optional.
• Figure 9 , a schematic representation of a method, or of a step, for monitoring the hydraulic network according to the invention. Steps shown in dotted lines are optional.
• Figure 10 , a schematic representation of a method according to the invention for correlating the consumption to the occupation of the installation.
• Figure 11 , a schematic representation of a method for controlling the quality of water on the hydraulic network according to the invention. Steps shown in dotted lines are optional.
• Figure 12 , a schematic representation of a method for managing non-sanitary equipment according to the invention. Steps shown in dotted lines are optional.

[Description of the invention]

In the remainder of the description, the term “ substantially equal ” is understood to mean a value varying by less than 30% with respect to the compared value, preferably less than 20%, even more preferably less than 10%. When substantially identical is used to compare shapes then the vectorized shape varies by less than 30% from the compared vectorized shape, preferably less than 20%, even more preferably less than 10%.

The term “installation ” is understood to mean a building comprising a plurality of floors and rooms or else a dwelling comprising one or more rooms. For example, in the context of a hotel, an installation can correspond to a building, a floor, a wing of the building or even a room.

The expression “ sanitary collector ”, also called feeders, corresponds, within the meaning of the invention, to devices intended for the distribution of hot and cold water in installations including sanitary and heating circuits as well as heating circuits. water supply. They make it possible to supply each water point to be served by its own circuit, which makes it possible to reduce variations in flow and temperature. The collectors allow a parallel supply of all the draw-off points.

The term " removable ", within the meaning of the invention corresponds to the ability to be detached, removed or dismantled easily without having to destroy the fixing means either because there is no fixing means or because the fixing means are easily and quickly removable (eg notch, screw, tongue, lug, clips, nut, thread). For example, by removable, it should be understood that the object is not fixed by welding or by another means not provided to allow the object to be detached. For example, a connection means capable of allowing a removable connection can be a threaded connection, a male female connection maintained for example by a triclamp or a flange connection. These connection means can also include seals.

By “ recovered water” or “collected water”, it is necessary to understand recovered water which is not distributed directly by the drinking water distribution network. This may correspond, for example, to rainwater or gray water collected at the installation level or even water collected at an eco-district level and accessible to the hydraulic integrator.

The term “solenoid valve”, within the meaning of the invention corresponds to a device making it possible to control or modify the flow of water in a pipe (a tube or a pipe) by using an electrical signal. It can for example integrate a solenoid or an electric motor.

For the purposes of the invention, the term “fluidly coupled ” should be understood to mean the fact that two parts (ie the hydraulic integrator and the extension) are arranged so as to allow the passage of a fluid from a first part to a first part. second part tightly (ie without any leakage). In particular, the parts are fluidly mounted in series by means of sanitary manifolds. Thus, the fluid can pass through a first sanitary manifold then a second sanitary manifold

In the remainder of the description, the terms “upstream” and “downstream” refer to the direction of the flow of the fluid.

In the remainder of the description, the same references are used to designate the same elements.

The Figure 1 shows schematically a hydraulic integrator 1 according to the invention.

The hydraulic integrator 1 according to the invention allows the centralized management of a hydraulic network of one or more installations. The installations can be industrial installations, of the office type, of the collective or domestic housing type. Preferably, the installations are of collective housing types.

The hydraulic integrator 1 according to the invention comprises at least one sanitary cold water collector 10, suitable for managing cold water. The cold water sanitary manifold 10 can include several distribution outlets 11. For example, it can include at least two distribution outlets, preferably at least three distribution outlets and even more preferably at least four distribution outlets. The cold water sanitary manifold 10 presented in figure 1 has four distribution outlets 11. Generally, a sanitary cold water manifold 10 has less than six distribution outlets. If the installation requires a greater number of outlets, then the hydraulic integrator 1 can include two or more sanitary cold water collectors so as to construct a hydraulic integrator 1 responding to the particular demand of the installation.

As presented in figure 1 , each of the distribution outlets 11 of the domestic cold water manifold 10 is equipped with a flowmeter 12 and a solenoid valve 13. The flowmeter 12 can for example be selected from an electromagnetic flowmeter, an ultrasonic flowmeter, a mass flowmeter or else a vortex flowmeter.

Advantageously, the sanitary cold water collectors 10 are equipped at the downstream end of each of the distribution outlets 11 with a connection means capable of allowing a removable connection. This facilitates the on-site installation of the hydraulic integrator 1.

Advantageously, the sanitary cold water collector 10 comprises at least one temperature sensor 14. This temperature sensor on the sanitary cold water collector can be used in hot countries so as to monitor the cold water inlet temperature and alert if it exceeds a limit value. This also makes it possible to explain a DHW temperature which would be too low if the preparation is carried out via a gas boiler which guarantees a delta T of 45 ° C. Such a probe can also allow a loop-back connection alert function by a control unit 50.

The sanitary cold water collector 10 has two ends 16 which can each advantageously comprise a connection means capable of allowing a removable connection. As can be seen on the figure 1 , the ends of the sanitary cold water manifold 10 are advantageously positioned at an edge of the support 80 so as to facilitate their junction with a water inlet. More preferably, one end 16 is intended to be connected to a means for producing domestic hot water 28 and the other being connected directly or indirectly to the supply of drinking water. In this case, the hydraulic integrator 1 according to the invention may further include a flowmeter positioned upstream of the domestic hot water production means 28, for example on the domestic cold water manifold 10 or upstream of the domestic cold water manifold. 10.

The means for producing hot water 28 can for example be an electric water heater with or without a balloon (instantaneous for example), a gas boiler with or without a balloon, thermodynamic or solar energy. Hot water can also be produced in a collective boiler room or a heating network.

As presented in figure 1 , the hydraulic integrator 1 comprises at least one domestic hot water manifold 20. This domestic hot water manifold 20 is configured to manage the distribution of hot water.

As presented in the figure 1 , this domestic hot water manifold 20 comprises at least one temperature sensor 24 and several distribution outlets 21. For example, it may have at least two distribution outlets, preferably at least three distribution outlets and even more preferably in at least four distribution outlets. The domestic hot water manifold 20 presented in figure 1 has three distribution outlets 21. Like a cold water sanitary manifold, a hot water sanitary manifold preferably has less than six distribution outlets. If the installation requires a greater number of distribution outlets then the hydraulic integrator 1 can include two or more domestic hot water collectors 20 so as to construct a hydraulic integrator 1 meeting the particular demand of the installation.

As presented in figure 1 , each of the distribution outlets 21 of the domestic hot water manifold 20 is equipped with a flowmeter 22 and a solenoid valve 23. These flowmeters 22 and solenoid valves 23 are preferably similar to the flowmeters 12 and solenoid valves 13 of the domestic cold water manifold 10.

Advantageously, the sanitary hot water collectors 20 are equipped at the downstream end of each of the distribution outlets 21 with a connection means capable of allowing a removable connection. This facilitates the on-site installation of the hydraulic integrator 1.

The sanitary hot water manifold 20 has two ends 26 which can each advantageously comprise a connection means capable of allowing a removable connection. As can be seen on the figure 1 , the ends of the domestic hot water manifold 20 are advantageously positioned at an edge of the support 80 so as to facilitate their junction with a hot water inlet. More preferably, both ends 26 comprise a connection means capable of allowing a removable connection, one end being connected to a means for producing domestic hot water 28 and the other being equipped with a screwed cap which can then serve as an inspection hatch to check the state of the collector.

Advantageously, the domestic hot water manifold 20 comprises two temperature probes 24. These temperature probes 24 are preferably located near each of its ends. For the purposes of the invention, the term “close” should be understood to mean less than ten centimeters, preferably less than five centimeters. As will be presented in the methods associated with the hydraulic integrator according to the invention, these temperature probes 24 can be configured to ensure a regular measurement of the temperature at each of the ends of the manifold so as to generate an alert aiming to inform of '' an increased risk of the formation of a biofilm comprising Legionella and which may constitute a health risk.

According to one embodiment, as shown in figure 2A , the hydraulic integrator may include a conduit 15 capable of connecting the sanitary cold water manifold 10 to a drinking water inlet. Preferably, the duct 15 has one end allowing a removable connection and preferably two ends allowing a removable connection. Advantageously, the end intended for connection to a drinking water inlet is positioned at an edge of the support 80 so as to facilitate its junction with a hot water inlet. The hydraulic integrator according to the invention may also include a conduit 19 capable of connecting a distribution outlet 11 of the domestic cold water manifold 10 to a means of producing hot water 28. This is particularly suitable when the installation has a dedicated means of hot water production. Preferably, the duct 19 has one end allowing a removable connection and preferably two ends allowing a removable connection. Advantageously, the end intended for connection to the means for producing hot water is positioned at an edge of the support 80 so as to facilitate its junction.

As presented in the figure 2A , the hydraulic integrator may further comprise a manifold 25 which can be connected to the means for producing hot water 28 by a conduit. The manifold 25 comprises, preferably at each of its two ends, a connection means 27 capable of allowing a removable connection to the means for producing hot water 28. This gives the hydraulic integrator great versatility allowing it to be easily connected to the means for producing hot water 28 and this regardless of the positioning of this means for producing hot water 28 with respect to the cold water inlets. Once the installation is complete, the end which is not connected to the means of hot water production 28 can be clogged. A connection means 27 is for example a threaded connector or a recessed tube connector. The collector 25 is preferably equipped at each of its two ends with a temperature sensor. The hydraulic integrator according to the invention can then include a duct 29 capable of connecting to the domestic hot water manifold 20 and to the manifold 25. Alternatively, the duct 29 is on the one hand connected to the domestic hot water manifold 20 and on the other hand. comprises, at its other end, a connection means capable of allowing a removable connection to the means for producing hot water 28. Advantageously, said other end is positioned at the level of an edge of the support 80 so as to facilitate its junction with a hot water supply. The collector 25 presented at the figure 2A has an outlet connected to a domestic hot water manifold 20 via a pipe 29. The manifold 25 can also include several outlets making it possible to supply several sanitary hot water manifolds 20.

The hydraulic integrator 1, as shown in figure 2A , further comprises a recovered water collector 30. The recovered water collector 30 according to the invention is suitable for managing collected water.

In the same way as the domestic hot water 20 and cold water 10 manifolds, the recovered water manifold 30 comprises several distribution outlets 31, each of said several distribution outlets being equipped with a flowmeter 32 and a solenoid valve 33. The A hydraulic integrator may include a conduit 35 connected to the manifold 30 which can be used to connect the manifold 30 to a storage means 38 for the collected water. Advantageously, the end intended for connection to a storage means 38 of collected water is positioned at an edge of the support 80 so as to facilitate its junction with an inlet of collected water.

Preferably, the hydraulic integrator 1 comprises at least one three-way duct, a first path being connected to a distribution outlet 11, a second path being connected to a distribution outlet 31 and a third path, the end of which is preferably positioned near an edge of the support 80, being adapted to be connected to an apparatus capable of accepting collected water.

Advantageously, the recovered water collector 30 are equipped at the downstream end of each of the distribution outlets 31 with a connection means capable of allowing a removable connection. This facilitates the on-site installation of the hydraulic integrator 1.

Advantageously, the control unit 50 is configured to receive information on the volume of collected water present in the storage means 38 of collected water. In this context, the solenoid valves 33 are advantageously able to define a flow rate being a function of the volume of collected water present in the storage means 38 of collected water. This makes it possible to control the volume of water present within the storage means 38 of collected water.

The water collected can, for example, be rainwater or gray water collected from the installation or even water collected from an eco-district. Preferably, this water has undergone a preliminary treatment before integration into the hydraulic network of the installation so as on the one hand to ensure the health safety of users and on the other hand not to damage the installations (eg microbial proliferation, corrosion, clogging, etc.). Thus, advantageously, the storage means 38 for collected water is associated with one or more means for treating the collected water. These treatment means can for example implement chemical treatments of the water collected, for example based on oxidants. Preferably, these treatment means are suitable for implementing physical treatments which can be selected from: sterilization by ultraviolet, treatment on activated carbon and / or filtration. Thus, the water collected can be treated, preferably before its storage.

As shown schematically on the figure 1 and the figure 2A , the hydraulic integrator 1 also comprises a control unit 50 capable of receiving information from flowmeters 12, 22, 32 and from temperature probes 14, 24 and capable of controlling all of the solenoid valves 13, 23, 33. The control solenoid valves include, for example, the control of closing, opening or even partial opening.

Since, unlike the system of the prior art, the management is centralized, the flowmeters 12, 22, 32, temperature probes 14, 24 and solenoid valves 13, 23, 33 can be advantageously connected to the control unit 50 in a wired way without this entailing significant costs. Alternatively, flowmeters 12, 22, 32, temperature probes 14, 24 and solenoid valves 13, 23, 33 can be connected to the control unit by wireless communication protocols such as wireless subnets (eg Zigbee , WIFI) and / or mobile (eg GPRS, UMTS).

The control unit 50 is advantageously configured to act as a processing unit and in particular to process the information received. The processing may for example correspond to a comparison of the values received with predetermined values, to the generation of an alert, to the recording of data on a data storage means, to the generation of a report and / or to the transmission of data. data. The control unit 50 is advantageously able to process commands from the operator in real time.

In addition, the control unit 50 can be connected to the means for producing hot water 28 and is able to control it so as to modify the temperature of the water leaving said. means for producing hot water 28. Thus, it is possible to control the means for producing hot water 28, in order to apply corrective measures (typically a thermal shock) in order to fight against the proliferation of legionella.

The hydraulic integrator 1 can further include a communication module 60 and / or a data storage means 70.

The communication module 60 is configured to receive and transmit information to remote systems such as tablets, telephones, watches, computers or servers and is thus able to allow communication between the control unit 50 and a computer. remote terminal. The terminal can thus interact remotely with the hydraulic integrator 1 according to the invention. The communication module 60 allows data to be transmitted over at least one communication network and may include wired or wireless communication. Preferably, the communication is operated via a wireless protocol such as wifi, 3G, 4G, and / or Bluetooth. The interaction can involve application software used by the operator to interact with the system according to the invention. The application software may for example be capable of interacting with the control unit 50 according to the invention and comprises a graphical interface making it possible to facilitate interaction with an operator. An operator can then act on the remote terminal so as to generate an instruction able to be implemented by the control unit 50 so as to act on the hydraulic network of the installation through the hydraulic integrator 1 according to the 'invention.

Advantageously, the communication module 60 is configured to receive and transmit information to an enclosure comprising a microphone and a speaker. In this case, the communication module can be associated with a conversion module capable of transforming sound message data into instruction data. Thus, a user can control the hydraulic integrator via a voice command made to the enclosure which will be transformed into instruction data for the control unit 50 and will be possible for him to receive information via this same enclosure.

The data storage means 70 may comprise a transient memory and / or a non-transient memory. It is suitable for recording, for example in the form of files, the raw values of temperature probes, flowmeters and the positions of solenoid valves. The non-transient memory can be a medium such as a memory card, or a hard disk hosted by a remote server. The microprocessor of the control unit 50, the data storage means 70 and the communication module 60 are generally interconnected by a bus. These means are distinct on the figure 1 but the invention can provide various types of arrangement such as for example a single module combining all the functions described here. Likewise, these means can be divided into several electronic cards or else grouped together on a single electronic card.

• Un conductimètre, permettant de mesurer les solides dissous totaux tels que les ions inorganiques dissouts dans l'eau (e.g. minéraux, sels ou métaux) ;
• Un pH-mètre, pour mesurer le pH de l'eau circulant dans le réseau. De préférence le pH-mètre est basé sur une technologie potentiométrique ;
• Un oxymètre, apte à mesurer la concentration en oxygène dans l'eau. De préférence l'oxymètre est basé sur une technologie optique via luminescence ou une technologie ampérométrique avec électrode de Clark (nickel/plomb) ;
• Un turbimètre, apte à mesurer la turbidité de l'eau, par exemple conformément à la norme DIN EN ISO 7027 et/ou la quantité de solides, par exemple conformément à la norme DIN 38414. De préférence le turbimètre est basé sur une technologie optique à base de diffusion ou d'absorption de lumière comme de la lumière infrarouge ou de la lumière blanche ;
• Une sonde de mesure des nitrates, apte à mesure la concentration en nitrate dans l'eau à partir de mesures UV, et
• Une sonde de mesure de la charge organique, apte à mesure la concentration en charge organique nitrate dans l'eau à partir de mesures UV.

The hydraulic integrator 1 can further include a means for controlling the quality of the water. The water quality control means is preferably selected from:

• A conductivity meter, making it possible to measure total dissolved solids such as inorganic ions dissolved in water (eg minerals, salts or metals);
• A pH meter, to measure the pH of the water circulating in the network. Preferably the pH meter is based on potentiometric technology;
• An oximeter, able to measure the oxygen concentration in the water. Preferably, the oximeter is based on optical technology via luminescence or amperometric technology with a Clark electrode (nickel / lead);
• A turbimeter, suitable for measuring the turbidity of water, for example in accordance with DIN EN ISO 7027 and / or the quantity of solids, for example in accordance with DIN 38414. Preferably the turbimeter is based on optical technology based on diffusion or absorption of light such as infrared light or white light;
• A nitrate measurement probe, suitable for measuring the nitrate concentration in the water from UV measurements, and
• An organic load measurement probe, suitable for measuring the organic nitrate load concentration in water from UV measurements.

Some means of water quality control can combine the control of several parameters. The water quality control means can be connected downstream of the drinking water inlet and upstream of the cold water sanitary collector 10. Advantageously, the presence of this water quality control means directly upstream of the sanitary cold water collector 10 makes it possible in particular to warn of a deterioration in the quality of the water entering the installation.

The hydraulic integrator 1 according to the invention can also be associated with a pressure regulator 40. The pressure regulator 40 can be connected downstream of the drinking water inlet and upstream of the cold water sanitary manifold 10, ie generally directly. after the water meter. Advantageously, the presence of this pressure regulator 40 directly upstream of the cold water sanitary manifold 10 makes it possible in particular to counteract the increase in pressure at night or during summer periods and thus significantly reduce water consumption by the installation. Thus, it is preferably positioned upstream of the cold water sanitary manifold 10.

The presence of a pressure regulator 40 in the hydraulic integrator according to the invention also makes it possible to quickly provide information on an inlet underflow at the level of the installation so as to make a diagnosis more quickly.

The admissible operating pressure within an individual installation is between 3.5 bars and 4.3 bars because beyond that the risk of deterioration of the diffusers (mixing valves, MAL solenoid valves, etc.) should not be neglected. Lower pressure can only affect the comfort or performance of the hydraulic network. Thus, the pressure regulator 40 is advantageously configured so as to maintain a pressure of between 3.5 bars and 4.3 bars within the installation.

Advantageously, the pressure regulator 40 is a preset and automatic pressure regulator 40, capable of automatically stabilizing the downstream pressure at a regulated value. Alternatively, the pressure regulator 40 can include a pressure sensor 41 with an adjustable pressure reducer 42.

The hydraulic integrator 1 according to the invention can also include one or more so-called ambient sensors capable of measuring parameters of the environment of the hydraulic integrator 1. The so-called ambient sensors can advantageously be selected from a temperature sensor. temperature (ie temperature of the ambient air in the installation), a humidity sensor, a barometer, a carbon dioxide sensor, a carbon monoxide sensor and a volatile organic compound sensor. Thus, the hydraulic integrator will be able to compare the temperature of the water and the temperature in the installation and for example be configured to modify predetermined minimum and maximum values of water temperature as a function of the temperature in the installation. The measurement of the carbon monoxide content could be used to alert in the event of toxicity of the air in the installation. The carbon dioxide content can be used to inform about the occupancy of the installation

In addition, the hydraulic integrator 1 comprises a support 80 on which the collectors are fixed, for example as shown on the figure 1 , the cold water 10 and hot water 20 sanitary collectors, as well as the recovered water collector 30 ( figure 2A ). The support 80 is suitable for being fixed against one of the walls of the installation. Thus, the hydraulic integrator with all these components can be directly installed without requiring the usual operations of threading, bending, drilling or welding on site.

As presented to figures 3A and 3B , the support 80 can advantageously comprise at least one plate of rigid polymer material 81. The support 80 has an overall density greater than 800 kg / m ³ , preferably, its overall density is greater than 1000 kg / m ³ and moreover more preferably, its overall density or density is between 1000 and 1500 kg / m ³ . Such a density makes it possible to facilitate the maneuverability of the hydraulic integrator. In addition, the hardness of the surface of the rigid polymer material 81 is advantageously greater than 40 as measured by the ISO 868 standard. Preferably, the hardness of the surface of the rigid polymer material 81 is greater than or equal to 45. The support 80 may include an expanded polymer 82 disposed on the plate of rigid polymeric material 81. In this case, the rigid polymeric material 81 and the expanded polymer 82 have different densities. The combination of these two polymers makes it possible to improve the properties of the support 80 and of the hydraulic integrator 1 in general so as to provide a prefabricated assembly which is robust while being easy to handle. For example, the rigid polymer material 81 has a density greater than 800 kg / m ³ , preferably greater than 1000 kg / m ³ . The expanded polymer 82 for its part has a density of less than 700 kg / m ³ , preferably less than 600 kg / m ³ . The density or density is preferably measured according to standard EN ISO 1183-1. As presented in the figure 3B , the support 80 may comprise two plates of rigid polymer 81 between which is disposed an expanded polymer 82. This arrangement forms a sandwich-type structure where the expanded polymer 82, a lower density structure, is surrounded by one or more polymer panels. rigid 81. The presence of the expanded polymer makes it possible to reduce the vibrations, linked to the flow of fluids in the pipes, having repercussions on the walls of the installation. Thus, this makes it possible to reduce noise pollution.

The thickness of the support 80 is generally less than 20 mm. Preferably, it is between 5 mm and 15 mm. Even more preferably, it is substantially equal to 10 mm. Likewise, controlling the thickness makes it possible to obtain a support that is sufficiently rigid to support all of the parts which constitute it while retaining a weight that does not make its handling complex or stressful.

The rigid polymer material 81 and the expanded polymer 82 can be composed of different polymers which can for example be selected from: (meth) acrylic polymers (eg PMMA-polymethyl methacrylate), saturated polyesters (eg PET-polyethylene terephthalate, PETG-Polyethylene Glycosilated Terephthalate, PBT- Polybutylene Terephthalate, PLA-Polylactic Acid), Polyethylene (PE), Polycarbonate (PC), Polyvinyl Chloride (PVC), Polyvinylidene Fluoride (PVDF), PVC chlorinated (CPVC), polyuretane (PU), polypropylene (PP). The rigid polymer material 81 and the polymer foamed 82 can also be made from copolymers. Preferably, the support consists of polyvinyl chloride and has a density greater than 1200 kg / m ³ .

The support advantageously comprises several fixing holes 83 making it possible to quickly fix the hydraulic integrator 1 to a wall. In addition, holes 84 may be provided so as to facilitate the fixing of the collectors on the support 80.

As presented in figure 1 , the collectors 10, 20, 30 are fixed to the support 80 by means of the fixing means 90. These fixing means are advantageously made of polymer material, and are for example polymers selected from the polymers proposed above for the rigid polymeric material 81 and the expanded polymer 82.

One of the causes of malfunction during the installation of the distribution network is that the removable connections have been tightened too strongly on site, leading at best to misalignment of the modules or, worse, damage to the connections between the various components of the distribution network. Thus, in order to reduce or eliminate these risks of damage during installation, the hydraulic integrator 1 advantageously comprises one or more means 91 for maintaining the collectors. The holding means 91 of the collectors preferably comprises a plate comprising openings 92 capable of allowing the ends of the distribution outlets 11, 21, 31 of the collectors to pass. Advantageously, said openings 92 have a shape substantially identical to the shape of a cross section of the end of the distribution outlet which has to pass through this retaining means 91. For example, on the figure 4 , the ends of the distribution outlets 11 and 21 comprise connection means corresponding to female hexagonal nuts with male thread and the openings 92 have a hexagon shape corresponding to the shape of a cross section of the nuts positioned at the ends 11 and 21. Preferably, each of the distribution outlets 11, 21 is connected to a connection means capable of allowing a removable connection, said connection means has a cross section having a geometric shape that is not circular and said hydraulic integrator comprises a retaining means 91 comprising one or more openings 92 whose shape is substantially identical to the shape of the cross section of the connecting means. The geometric shape of a cross section of the connection means, and therefore the opening 92, preferably has at least one vertex, more preferably it is a polygon and even more preferably a hexagon. More broadly, the cross section can be a geometric shape not exhibiting central symmetry.

The retaining means 91 is advantageously fixed to the support 80 in a manner perpendicular or substantially perpendicular to said support 80. It is also positioned so as to so that the ends of the distribution outlets 11, 21, 31, and more particularly the connection means capable of allowing a removable connection, are inserted into the openings 92. However, given that the openings 92 have a substantially identical shape in the shape of a cross section of the end of the distribution outlet which has to pass through this support, or where appropriate a shape substantially identical to the connection means capable of allowing a removable connection, then it is no longer possible to damage the hydraulic integrator when tightening at these connections.

These holding means 91 are advantageously made of polymer material, and are for example compounds selected from the polymers proposed above for the rigid polymer material 81 and the expanded polymer 82.

These retaining means 91 can also be used to block the ends 16 and 26 of the sanitary collectors respectively cold water and hot water.

The sanitary collectors are for example mainly made of copper or brass. Preferably, they consist predominantly of copper. Thus, they add additional protection against the development of Legionella in the installation's hydraulic network.
The tubes (pipe, conduit) for example connecting the collectors to one another as well as the collectors to the means for producing hot water 28 are also preferably made of copper.

The hydraulic integrator 1 can also include a facade or a cover, for example made of metal or polymers which may or may not be perforated. This facade or hood covering the components of the hydraulic integrator protects them. In addition, this facade or this cover can integrate light-emitting diodes (LEDs) which can be used to inform the user of the status of the hydraulic integrator and therefore of the status of the water network. The LEDs may be of different colors and be configured to constitute an alert system in the event of a malfunction. The LEDs are advantageously positioned so as to form a light projection on a support and in particular so as to allow projection against one of the walls of the installation. In addition, the cover has openings which can act as ventilation and preferably positioned near the control unit.

The hydraulic integrator according to the invention can be used individually for an installation and for example be suitable for centralized water management in offices or in an apartment. Alternatively, it can be used in association with one or more auxiliary hydraulic integrators 2. The control unit of the hydraulic integrator 1 is suitable for, preferably configured to, receive, from these auxiliary hydraulic integrators 2, information from flowmeters. and temperature sensor and is suitable, or may be suitable, to control the solenoid valves of these one or more auxiliary hydraulic integrators 2. Use in combination means that the hydraulic integrator 1 is able to communicate with the auxiliary hydraulic integrator 2. It can thus receive and transmit information to one or more integrators remote auxiliary hydraulics. In particular, an auxiliary hydraulic integrator can be configured to operate autonomously and possibly send information to the hydraulic integrator. Alternatively, it can be controlled by the hydraulic integrator. Preferably, the communication is operated via a wireless protocol such as wifi, 3G, 4G, and / or Bluetooth.

• un collecteur sanitaire eau froide, apte à la gestion de la distribution d'eau froide, comportant plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• un collecteur sanitaire eau chaude, apte à la gestion de la distribution d'eau chaude, comportant au moins deux sondes de température et plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• une unité de commande apte à recevoir des informations de débitmètres et de sonde de température et apte à contrôler l'ensemble des électrovannes ;
• un module de communication 60 et un moyen de stockage de données 70 ; et
• un support sur lequel sont fixés les collecteurs sanitaires eau froide et eau chaude, ledit support étant destiné à être fixé contre l'un des murs de l'installation.

In these cases, the hydraulic integrator 1 according to the invention constitutes the main hydraulic integrator and is coupled to auxiliary hydraulic integrators 2, said auxiliary hydraulic integrators 2 comprising:

• a cold water sanitary manifold, suitable for managing the distribution of cold water, comprising several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• a domestic hot water manifold, suitable for managing the distribution of hot water, comprising at least two temperature probes and several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• a control unit able to receive information from flowmeters and temperature probe and able to control all of the solenoid valves;
• a communication module 60 and a data storage means 70; and
• a support on which the cold water and hot water sanitary collectors are fixed, said support being intended to be fixed against one of the walls of the installation.

In addition, the hydraulic integrator 1 according to the invention can be used with one or more extensions 3 illustrated on figure 2B . An extension 3 makes it possible to multiply the number of outlets of the hydraulic integrator 1 or to add the possibility of managing other water networks such as rainwater or treated gray water.

For example, if the hydraulic integrator 1 does not have enough outlets to be able to supply and therefore manage all the equipment of a dwelling or a dwelling, then the extension will be fluidly coupled to the hydraulic integrator on the cold water 10 and hot water 20 sanitary collectors. The extension 3 can also be used to give the hydraulic integrator 1 the possibility of managing other water networks.

The fluidic coupling can be achieved using any sealed fixing means making it possible to join two pipes. It can for example be selected from flanges, metal or polymer fittings such as quick cylindrical fittings (eg of the "push-fit" type in English terminology) or junction fittings, screw fittings or bellows fittings. .

• un collecteur sanitaire eau froide, apte à la gestion de la distribution d'eau froide, comportant plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ;
• un collecteur sanitaire eau chaude, apte à la gestion de la distribution d'eau chaude, comportant au moins deux sondes de température et plusieurs sorties de distribution, chacune desdites plusieurs sorties de distribution étant équipées d'un débitmètre et d'une électrovanne ; et
• un support sur lequel sont fixés les collecteurs sanitaires eau froide et eau chaude, ledit support étant destiné à être fixé contre l'un des murs de l'installation.

As presented in the figure 2B , the extension 3 according to the invention comprises

• a cold water sanitary manifold, suitable for managing the distribution of cold water, comprising several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve;
• a domestic hot water manifold, suitable for managing the distribution of hot water, comprising at least two temperature probes and several distribution outlets, each of said several distribution outlets being equipped with a flowmeter and a solenoid valve; and
• a support on which the cold water and hot water sanitary collectors are fixed, said support being intended to be fixed against one of the walls of the installation.

Thus, extension 3 is similar to hydraulic integrator 1 or auxiliary hydraulic integrator 2 except that it does not include a control unit or communication module. Extension 3 is therefore not an autonomous system capable of processing data and managing water flows independently.

In addition, the extension 3 can have the same embodiments as the hydraulic integrator 1 and in particular preferred or advantageous modes concerning the collectors and / or the support.

According to another aspect, the invention also relates to a method for centralized management of a hydraulic network of one or more installations implementing the hydraulic integrator according to the invention and comprising a recording step during which values from flow meters, temperature probes and / or solenoid valves are recorded on a data storage medium.

Such a method makes it possible in particular to control each of the solenoid valves. Thus, the method of centralized management of a hydraulic network may include a step of receiving a solenoid valve control instruction, by the communication unit, said instruction comprising a solenoid valve identifier making it possible to select the solenoid valve to check and a status value to check the status of the solenoid valve. Instructions may be transmitted by any client capable of communicating with the communication module (eg computer, cell phone).

The method can also include the generation of a file comprising the records as a function of time of water consumption (e.g. flow rates) and temperatures.

In addition, via the method for centralized management of a hydraulic network according to the invention, the hydraulic integrator 1 according to the invention can interact with another hydraulic system equipped with a control unit or a communication module. Thus, the centralized management method can also include a step of sending or receiving data or instructions to a hydraulic system, for example selected from: a device for preparing hot water, a household appliance, a heating system. heating, ventilation and / or air conditioning, a rainwater harvesting system, a wastewater reuse system, a wastewater heat recovery system, a swimming pool pump system and an irrigation system.

• Acquisition 110 par une unité de commande, de valeurs de températures transmises par une ou plusieurs sondes de température,
• Comparaison 120, par l'unité de commande, des valeurs de température transmises à des valeurs maximales prédéterminées,
• Comparaison 130, par l'unité de commande, des valeurs de température transmises à des valeurs minimales prédéterminées,
• Génération 140, par l'unité de commande, d'une alerte si les valeurs de température transmises dépassent les valeurs maximales prédéterminées ou sont inférieures aux valeurs minimales prédéterminées.

The hydraulic integrator 1 according to the invention can be used within the framework of a method for monitoring the temperature 100 of the water on the hydraulic network as illustrated in figure 5 . The monitoring of the water temperature 100 on the hydraulic network comprises the following steps:

• Acquisition 110 by a control unit, of temperature values transmitted by one or more temperature probes,
• Comparison 120, by the control unit, of the temperature values transmitted to predetermined maximum values,
• Comparison 130, by the control unit, of the temperature values transmitted to predetermined minimum values,
• Generation 140, by the control unit, of an alert if the temperature values transmitted exceed the predetermined maximum values or are lower than the predetermined minimum values.

During the acquisition step 110, these are preferably temperature values transmitted by temperature probes 24 placed on domestic hot water collectors 20 which are acquired by the control unit 50. If necessary, there is a also acquisition of the temperature values transmitted by temperature probes 24 placed on a collector 25 connected to a means for producing hot water 28. Finally, there may also be acquisition of the temperature values transmitted by one or more temperature probes. temperature 14 placed on a sanitary cold water collector 10.

This monitoring reduces the risk of burns and allows better control of the electricity consumption of the means of generating hot water. It also helps reduce the risk of legionella development.

Advantageously, the step 140 of generating an alert can be followed by a step of generating 141 of an anomaly report that can be directly transmitted to a company, for example a company specializing in the maintenance of the means of production of Hot water.

This monitoring of the temperature 100 of the water can comprise first steps 101 corresponding to the definition of the predetermined maximum and minimum values. Limits for these values are generally defined by standards but within the framework of the method 100, the operator can, while respecting the standards in force, customize the predetermined minimum and maximum values. This definition can for example be achieved by means of an external interface connected via a wireless connection to the hydraulic integrator 1 according to the invention.

• Définition 210 d'un groupe d'équipements où chaque équipement est relié à au moins une sortie de distribution d'un même collecteur sanitaire,
• Définition 220 d'une valeur de débit total critique pour ledit groupe d'équipements,
• Définition 230, au sein du groupe d'équipements, d'un ou plusieurs équipement(s) non prioritaire(s),
• Acquisition 240 par l'unité de commande, de valeurs de débit transmises par des débitmètres, pour chacune des sorties de distribution reliées aux équipements dudit groupe d'équipements,
• Comparaison 250 de la somme des valeurs de débit des équipements du groupe d'équipements à la valeur de débit total critique pour ledit groupe d'équipements,
• Génération 260, si la somme des valeurs de débit des équipements du groupe d'équipements dépasse la valeur de débit total critique pour ledit groupe d'équipements, d'une instruction de réduction du débit aux électrovannes associées aux sorties de distribution reliées aux équipements non prioritaires dudit groupe d'équipements.

It happens that in some installations, too much water consumption at a given moment causes disturbances in the flow of water arriving at one or more equipment. However, such a disturbance in the flow can have consequences on the correct operation of certain equipment or simply generate discomfort for the users. This problem can be solved by implementing a method of prioritizing equipment according to the invention. Thus, the invention also relates to a method, or a step, for prioritizing 200 equipment as illustrated in figure 6 . Equipment prioritization 200 involves the following steps:

• Definition 210 of a group of equipment where each equipment is connected to at least one distribution outlet of the same sanitary manifold,
• Definition 220 of a critical total flow value for said group of equipment,
• Definition 230, within the equipment group, of one or more non-priority equipment (s),
• Acquisition 240 by the control unit of flow values transmitted by flow meters, for each of the distribution outputs connected to the equipment of said group of equipment,
• Comparison 250 of the sum of the throughput values of the devices of the group of devices with the critical total flow value for said group of devices,
• Generation 260, if the sum of the throughput values of the devices of the group of devices exceeds the critical total flow value for said group of devices, an instruction to reduce the flow to the solenoid valves associated with the distribution outlets connected to non-priority devices of said group of devices.

During the step of defining the equipment group 210, the equipment items can be grouped together by equipment dependent on the same collector so as for example to form one group per collector. Alternatively, the grouping can be done on several collectors.

Advantageously, when defining 220 a critical total flow value for said group of equipment, it is possible to differentiate a critical total hot water flow value and a critical total cold water flow value.

The definition 220 of a critical total flow rate value for said group of equipment can advantageously be implemented to choose a flow rate value beyond which there is a risk of fluctuation in the flow rate of the water arriving at the equipment. Such a method can for example be implemented to ensure a flow of hot water for the shower.

The definition steps 210, 220, 230 can be carried out for the first time at the initiation of the method, while the acquisition steps 240 and comparison 250 are generally repeated so as to allow continuous monitoring. The definition steps can be repeated from time to time to modify the values associated with them.

• Définition 410 d'un groupe d'équipements eau collectée où chaque équipement est apte à utiliser de l'eau collectée et est relié à une sortie de distribution d'un collecteur eau récupérée,
• Définition 420 d'une valeur minimale de volume d'eau collectée,
• Acquisition 430, par l'unité de commande, d'une valeur de volume actuel d'eau collectée présent dans un moyen de stockage d'eau collectée,
• Comparaison 440 de la valeur de volume actuel d'eau collectée à la valeur minimale de volume d'eau collectée, et
• Génération 450, si la valeur de volume actuel d'eau collectée dépasse la valeur minimale de volume d'eau collectée, d'une instruction d'ouverture des électrovannes positionnées sur les sorties de distribution, du collecteur eau récupérée, reliées aux équipements appartenant au groupe d'équipement eau collectée.

With the increase in population, drinking water resources are increasingly controlled and there is a need for the development of systems or methods that allow the use of collected water as much as possible for applications where the use of potable water is not essential. The present invention provides a solution to this growth problem. For this, the invention also relates to a method, or a step, for managing 400 collected water as illustrated in figure 7 . This collected water management comprises the following stages:

• Definition 410 of a group of collected water equipment where each equipment is able to use collected water and is connected to a distribution outlet of a collected water collector,
• Definition 420 of a minimum value of the volume of water collected,
• Acquisition 430, by the control unit, of a current volume value of collected water present in a collected water storage means,
• 440 comparison of the current volume value of collected water to the minimum value of collected water volume, and
• Generation 450, if the current volume value of collected water exceeds the minimum value of the volume of collected water, an instruction to open the positioned solenoid valves on the distribution outlets, of the collected water collector, connected to the equipment belonging to the collected water equipment group.

Such a method can be implemented in association with a means for storing collected water capable of measuring the volume of collected water being stored at a given instant, the measurement preferably being carried out continuously. Such a measurement can for example be carried out by level sensors of the laser, ultrasonic or float sensor type. The means for storing the collected water can also include a temperature probe. Water can be transported by controlled pumps or pressure differential pumps.

This method of managing the collected water can further comprise a definition of a maximum value of the volume of collected water which may correspond to the maximum storage volume of the means for storing the collected water. In this context, the method for managing the collected water can also include a generation step 460, if the current volume value of collected water exceeds the maximum value of the volume of water collected, of an alert. This alert can advantageously be followed by an instruction to close solenoid valves positioned upstream of the means for storing the collected water or by an instruction to open a purge solenoid valve for the means for storing the collected water. .

In addition, this method of managing the collected water can comprise a step of measuring the quantity of reused water. This method can also include a step of generating an instruction to close the solenoid valves positioned on the distribution outlets of the recovered water collector 30 if the current volume value of water collected is less than the minimum value of the volume of water collected. .

The equipment suitable for using the collected water are, for example, toilets, washing machines or even water distribution systems for sprinkling. Since in some countries, gray water, which contains solvents and other chemicals, may be prohibited in connection with sprinkling, the hydraulic integrator can be connected to two reservoirs, one containing gray water and the other rainwater.

The water collected can also be used to fill aquaponics ponds or irrigate urban plantations such as plants located on terraces, indoors or on roofs.

The definition steps 410, 420 can be carried out for the first time at the initiation of the method, while the acquisition 430 and comparison steps 440 are generally repeated so as to allow continuous monitoring. The definition steps can be repeated from time to time to modify the values associated with them.

In addition, the method according to the invention can take into account the time so as to favor operation during certain time slots. This can be advantageous when the actions require significant electrical resources, for example to favor electricity consumption during off-peak hours or during periods of renewable energy production. In this case, the method also integrates a step of comparing the current time to predetermined times so as to initiate actions only if the current time corresponds to the predetermined operating times.

• Définition 510 d'une valeur minimale de pression sur le réseau et d'une valeur maximale de pression sur le réseau, par exemple comprise entre 3,5 et 4,3 bar,
• Acquisition 520, par l'unité de commande, d'une valeur de pression actuelle sur le réseau, mesurée par un capteur de pression positionné en amont du collecteur sanitaire eau froide,
• Comparaison 530 de la valeur actuelle de pression sur le réseau aux valeurs minimale et maximale de pression sur le réseau,
• Génération 540, si la valeur actuelle de pression sur le réseau dépasse la valeur maximale de pression sur le réseau, d'une instruction de réduction de pression à un réducteur de pression réglable, et
• Génération 550, si la valeur actuelle de pression sur le réseau est inférieure à la valeur minimale de pression sur le réseau, d'une instruction d'augmentation de pression à un réducteur de pression réglable.

In some installations or regions, an increase in pressure on the water network can be observed, at night or during the summer. These increases can lead to a significant increase in water consumption by the installation and / or a deterioration of networks and sanitary equipment (mixing valves in particular). The present invention proposes a solution to this problem. For this, the invention also relates to a method, or a step, for regulating the pressure 500 on the hydraulic network as illustrated in figure 8 . This pressure regulation comprising the following substeps:

• Definition 510 of a minimum pressure value on the network and a maximum pressure value on the network, for example between 3.5 and 4.3 bar,
• Acquisition 520, by the control unit, of a current pressure value on the network, measured by a pressure sensor positioned upstream of the domestic cold water manifold,
• Comparison 530 of the current value of pressure on the network with the minimum and maximum values of pressure on the network,
• Generation 540, if the current network pressure value exceeds the maximum network pressure value, from a pressure reduction instruction to an adjustable pressure reducer, and
• Generation 550, if the current network pressure value is lower than the minimum network pressure value, from a pressure increase instruction to an adjustable pressure reducer.

• Définition 610 d'au moins une valeur standard de consommation d'eau en fonction du temps pour ladite installation,
• Acquisition 620, par l'unité de commande, d'une valeur actuelle de débit pour chaque sortie de distribution des collecteurs sanitaire et de préférence enregistrement sur un moyen de stockage de données,
• Traitement 630 des valeurs de débit enregistrées de façon à obtenir une valeur actuelle de consommation en eau en fonction du temps,
• Comparaison 640 de la valeur actuelle de consommation en eau à la valeur standard de consommation d'eau pour une même période de temps, de préférence dans un référentiel calendaire, et
• Génération 650, si la valeur actuelle de consommation en eau dépasse la valeur standard de consommation d'eau pour une même période de temps, de préférence dans un référentiel calendaire, d'une alerte de consommation inhabituelle.

Still within the framework of a reasoned consumption of drinking water, the invention also relates to a method, or a step, of monitoring 600 of the hydraulic network as illustrated in figure 9 , said monitoring 600 of the hydraulic network comprising the following steps:

• Definition 610 of at least one standard value of water consumption as a function of time for said installation,
• Acquisition 620, by the control unit, of a current flow value for each distribution outlet of the sanitary manifolds and preferably recording on a data storage means,
• Treatment 630 of the recorded flow values so as to obtain a current value of water consumption as a function of time,
• Comparison 640 of the current water consumption value to the standard water consumption value for the same period of time, preferably in a calendar frame of reference, and
• Generation 650, if the current water consumption value exceeds the standard water consumption value for the same period of time, preferably in a calendar repository, an unusual consumption alert.

The step of definition 610 as a function of time is very advantageously carried out in a calendar system making it possible to take into account the seasonality of water consumption. Indeed, the water consumption of each item of equipment in an installation is seasonal and this affects the overall water consumption of an installation. Thus, preferably, the definition 610 of at least one standard value of water consumption as a function of time for said installation, comprises a standard value of water consumption as a function of time for each item of equipment and these values per item of equipment are entered in the configuration file as a function of time in a calendar repository. For example, the standard value of water consumption by a device is entered in the configuration file as a function of time in a reference system of a calendar day, calendar week, calendar month or calendar year. More preferably, considering the strong impact of the seasons on water consumption, the standard value of water consumption by a device is entered in the configuration file as a function of time in several benchmarks including a calendar week benchmark, of calendar month and calendar year. More preferably, the standard value of water consumption by an item of equipment is entered in the configuration file at least as a function of time in a calendar week reference.

The comparison 640 of the current value of water consumption to the standard value of water consumption for the same period of time can be implemented by means of a data processing module and it can be performed by statistical methods. known. The standard values of water consumption can then be predetermined values.

Preferably, the comparison step 640 can be carried out from comparison or learning models such as: neural network, Kernel, Multiple kernel learning, Support vector machine, decision trees, logistic regression, multiple regression and / or the nearest neighbors method. A model is generally a finite series of operations or instructions making it possible to qualify the water consumption, that is to say classify the water consumption values within predefined groups Y, or to prioritize these consumptions within a classification, so as to determine whether or not the consumption is unusual. The implementation of this finite series of operations makes it possible for example to attribute a label Y ₀ to an observation described by a set of characteristics X ₀ thanks for example to the implementation of a function f capable of reproducing Y having observed X.

In this context, more preferably, the comparison step 640 is based on a model, trained on a data set and configured to predict a standard value of water consumption at a given time. More particularly, this prediction is based on data sets comprising information on the water consumption values and the instant of measurement of these values. For example, for calibration purposes it is possible to use a dataset from a set of users with similar water needs. However, more advantageously, the data set can include values corresponding to the water consumption values recorded in this installation. Preferably, the comparison step 640 then comprises the use of a supervised statistical learning model.

Thanks to this, the monitoring method according to the invention can more effectively identify a deviation from the habits of the users of the installation.

Thus, the standard water consumption values can come from reference water consumption, from water consumption spent in this installation or advantageously from self-learning. There can be as many values as there are equipment on the installation. These values can also be modified to take into account changes in the habits of the user (s) of the installation.

The method can also include a step of generating and sending a notification proposing to shut off the water supply to the equipment concerned with, for example, the generation of an instruction to automatically close the solenoid valve by pressing it. absence of operator instruction for a predefined period of time.

Advantageously, the method according to the invention can also include a step of comparing the values originating, for example in real time, from temperature probes and / or solenoid valves with standard values for these devices.

• Définition 810 d'une valeur minimale et/ou maximale d'un paramètre relatif à la qualité de l'eau sur le réseau, par exemple une valeur maximale de conductivité,
• Acquisition 820, par l'unité de commande, d'une valeur de paramètre relatif à la qualité de l'eau sur le réseau, mesurée par un moyen de contrôle de la qualité de l'eau, le moyen de contrôle de la qualité de l'eau étant par exemple un conductimètre,
• Comparaison 830 par l'unité de commande, de la valeur actuelle du paramètre relatif à la qualité de l'eau aux valeurs minimale et/ou maximale définies, par exemple la conductivité,
• Génération 840 par l'unité de commande, si la valeur actuelle de pression du paramètre relatif à la qualité de l'eau indique une dégradation de la qualité de l'eau, d'une instruction de fermeture d'électrovannes. Par exemple, dans le cadre de la conductivité, un dépassement de la valeur maximale définie indique une dégradation de la qualité de l'eau.

In some regions, occasional deterioration in the quality of the water distributed via the networks can be observed. These degradations can lead to health risks for the users of an installation if they consume unsanitary water. The present invention proposes a solution to this problem. For this, the invention also relates to a method, or a step, for controlling the quality of the water on the hydraulic network. 800 as illustrated on figure 10 . This water quality control comprising the following sub-steps:

• Definition 810 of a minimum and / or maximum value of a parameter relating to the quality of the water on the network, for example a maximum value of conductivity,
• Acquisition 820, by the control unit, of a parameter value relating to the quality of the water on the network, measured by a water quality control means, the water quality control means water being for example a conductivity meter,
• Comparison 830 by the control unit, of the current value of the water quality parameter with the defined minimum and / or maximum values, for example conductivity,
• Generation 840 by the control unit, if the current pressure value of the parameter relating to the water quality indicates a degradation of the water quality, of an instruction to close solenoid valves. For example, in the context of conductivity, exceeding the set maximum value indicates a deterioration in water quality.

The generation of a solenoid valve closing instruction can be completed by the generation by the control unit, of an alert and possibly of an instruction to proceed once the water quality has returned to normal, to the flushing of the installation.

The method according to the invention can also comprise a step of measuring the concentration of carbon dioxide in the air of the installation and a comparison of the value of carbon dioxide measured with a standard value of concentration of carbon dioxide. The standard value of carbon dioxide concentration is preferably a predetermined value for the same period of time. The standard or predetermined carbon dioxide concentration values can come from reference values, from average carbon dioxide values measured in this installation or advantageously from self-learning. These values can also be modified to take into account changes in the habits of the user (s) of the installation.

The method can then compare the measured carbon dioxide concentration to a standard value of carbon dioxide concentration in order to determine whether an unusual water consumption can be justified by the presence of a greater number of users in the system. installation. Indeed, once normalized with regard to the habits of home or office users (definition of predetermined values), the carbon dioxide concentration can be correlated with the water consumption in the installation. For example, in the presence of a very low concentration of CO ₂ , reflecting an unoccupied place, the water consumption is reduced compared to the periods when the installation is occupied (generally associated with a higher concentration of carbon dioxide).

In addition, the method may include measurements of CO and VOC concentration, a comparison of the measured values with standard values and the generation of an alert on the degradation of the air quality in the installation in the event of exceedance of standard values.

Measuring the CO concentration can also make it possible to identify incomplete combustion which may be harmful to the occupants of the installation. Thus, a combined measurement of CO, VOC, CO ₂ and ambient temperature can allow the detection of the start of a fire.

• Acquisition 940, par l'unité de commande, d'une valeur de mesurée de consommation d'eau par un équipement non sanitaire,
• Comparaison 950 de la valeur de consommation d'eau par un équipement non sanitaire à une valeur de consommation d'eau prédéterminée, et
• Génération 960, si la consommation mesurée dépasse la valeur de consommation d'eau prédéterminée, d'une instruction d'alerte de consommation inhabituelle et/ou de fermeture d'une vanne associée audit équipement non sanitaire.

The sanitary network is not the only hydraulic network of an installation and equipment can also benefit from centralized management. Thus, the centralized management method in combination with the hydraulic integrator can also be used to manage the distribution of water to specialized equipment which is not associated with the sanitary networks. For this, the invention also relates to a method, or a step, for managing non-sanitary equipment 900 as illustrated in figure 11 . This management of non-sanitary equipment comprises the following steps:

• Acquisition 940, by the control unit, of a measured value of water consumption by non-sanitary equipment,
• Comparison 950 of the water consumption value by non-sanitary equipment with a predetermined water consumption value, and
• Generation 960, if the measured consumption exceeds the predetermined water consumption value, of an unusual consumption alert instruction and / or closing of a valve associated with said non-sanitary equipment.

The method can also include a step 910 of defining non-sanitary equipment where each item of equipment is able to use water and is connected to at least one distribution outlet of a sanitary manifold and defining a consumption value d. water predetermined by each non-sanitary equipment, preferably by period of time.

The method can also include a step 920 of receiving an instruction to open a valve associated with said non-sanitary equipment. In this case, the non-sanitary equipment concerned can interact with the hydraulic integrator so as to command it to open or close valves. In addition, the method can also include a step transmission 970 of water consumption data intended for said non-sanitary equipment.

In particular, the method can also comprise a step 930 of sending a control instruction to said non-sanitary equipment. Thus, in certain cases, the method according to the invention allows the hydraulic integrator to control the operation of the non-sanitary equipment.

All the methods described above can be implemented independently but are advantageously implemented by the hydraulic integrator according to the invention.

Since the hydraulic integrator corresponds to a prefabricated set of conduits and collectors, it is possible to know from manufacture what equipment will be connected to each of the distribution outlets 11, 21, 31. Thus, during its manufacture, it There may be a recording on the storage means 70 of an identifier associating an item of equipment with each of the distribution outlets 11, 21, 31 as well as a recording of associated predetermined values such as flow or temperature values.

In addition, the hydraulic integrator according to the invention is simple and quick to install in an installation, in particular in an installation under construction. Fixing to the wall can be done by a simple hooking drilled at 6 mm. The ends of the conduits or pipes of the water sub-circuits of the hydraulic network are then to be connected, preferably in a removable manner, for example by following a system of pictograms, conduit or to the appropriate distribution outlet 11, 21, 31 of the hydraulic integrator. In addition, the retaining means prevents damage caused by over-tightening carried out during installation on site and further reduces the risk of faulty workmanship.

Thus, thanks to the hydraulic integrator according to the invention, it is possible to install centralized management of the water network in just a few tens of minutes, whereas this could take several hours with the systems of the prior art. In addition, the risks of accidents and poor workmanship will have been reduced.

In addition, because of all these advantages, it is possible to equip installations in a simple, rapid and less expensive way than what was possible until now.

Claims (15)

1. A hydraulic integrator (1) for centralised management of a hydraulic network of one or more facilities, said integrator comprising:

   - at least one cold-water sanitary mains (10) capable of distributing cold water, comprising several distribution outlets (11), each of said several distribution outlets (11) being fitted with a flow meter (12) and a solenoid valve (13);

   - at least one hot-water sanitary mains (20) capable of distributing hot water, comprising at least one temperature probe (24) and several distribution outlets (21), each of said several distribution outlets (21) being fitted with a flow meter (22) and a solenoid valve (23);

   - a control unit (50) capable of receiving information from flow meters (12, 22) and the temperature probe (24) and capable of controlling all the solenoid valves (13, 23); and

   - a mounting (80) on which the control unit (50) and the cold-water (10) and hot-water (20) sanitary mains are fixed, said mounting (80) being intended to be fixed against one of the walls of the facility.
2. The integrator according to claim 1, characterised in that the hot-water sanitary mains (20) is fitted at each of its two ends (26) with a temperature probe (24) and attachment means (27) capable of allowing a removable connection to hot-water production means (28).
3. The integrator according to any one of claims 1 or 2, characterised in that it further comprises a reclaimed water mains (30) capable of distributing collected water, comprising several distribution outlets (31), each of said several distribution outlets being fitted with a flow meter (32) and a solenoid valve (33).
4. The integrator according to any one of claims 1 to 3, characterised in that the at least one cold-water sanitary mains (10) is fitted at the downstream end of each of the distribution outlets (11) with coupling means capable of allowing a removable connection.
5. The integrator according to any one of claims 1 to 4, characterised in that the at least one cold-water sanitary mains (10) comprises at least one temperature probe (14).
6. The integrator according to any one of claims 1 to 5, characterised in that the flow meters (12, 22, 32), temperature probes (14, 24) and solenoid valves (13, 23, 33) are connected to the control unit (50) by wire.
7. The integrator according to any one of claims 1 to 6, characterised in that the mounting (80) comprises at least one plate made of rigid polymer material (81) exhibiting a density greater than 800 kg/m3.
8. The integrator according to any one of claims 1 to 7, characterised in that it comprises at least one water quality control means selected from: conductometer, pH meter, oximeter, turbidimeter, nitrate-measuring probe, and organic load-measuring probe.
9. The integrator according to any one of claims 1 to 8, characterised in that it comprises at least one so-called ambient sensor selected from: a temperature sensor, a humidity sensor, a barometer, a carbon dioxide sensor, a carbon monoxide sensor and a volatile organic compound sensor.
10. The integrator according to any one of claims 1 to 9, characterised in that each of the distribution outlets (11, 21) is connected to coupling means capable of allowing a removable connection, said coupling means has a transversal cross-section having a geometric form not being circular, and said hydraulic integrator comprises holding means (91) comprising one or more openings (92) whereof the form is substantially identical to the form of the transversal cross-section of said coupling means.
11. A centralised management system of water supply to a hydraulic network of one or more facilities comprising a hydraulic integrator according to any one of claims 1 to 10 and at least one hydraulic auxiliary integrator (2).
12. A management process of the centralisation of the water supply to a hydraulic network of one or more facilities implementing the hydraulic integrator according to any one of claims 1 to 10, said process comprising a recording step during which information on flows, generated by flow meters, and/or information on temperatures, generated by temperature probes, is recorded on data storage means.
13. The management process according to claim 12 characterised in that it comprises a prioritisation step (200) for equipment, said prioritisation step (200) for equipment comprising the following steps:

    - Definition (210) of a set of equipment where each equipment is connected to at least one distribution outlet of the same sanitary mains,

    - Definition (220) of a total flow value critical for said set of equipment,

    - Definition (230), within the set of equipment, of one or more non-priority equipment,

    - Acquisition (240) by the control unit of the flow values, transmitted by the flow meters, for each of the distribution outlets connected to the equipment of said set of equipment,

    - Comparison (250) of the sum of the flow values of the equipment of the set of equipment with the total flow value critical for said set of equipment,

    - Generation (260), if the sum of the flow values of the equipment of the set of equipment exceeds the total flow value critical for said set of equipment, of a reduction instruction of the flow to the solenoid valves attached with the distribution outlets connected to the non-priority equipment of said set of equipment.
14. The management process according to any one of claims 12 or 13, characterised in that it comprises a management step (400) of collected water, said management step of collected water comprising the following steps:

    - Definition (410) of a set of equipment collected water where each equipment is capable of utilising collected water and is connected to a distribution outlet of a reclaimed water mains (30),

    - Definition (420) of a minimal value of volume of collected water,

    - Acquisition (430), by the control unit, of a current volume value of collected water present in storage means of collected water,

    - Comparison (440) of the current volume value of collected water with the minimal value of volume of collected water, and

    - Generation (450), if the current volume value of collected water exceeds the minimal value of volume of collected water, of an instruction to open the solenoid valves positioned on the distribution outlets, of the reclaimed water mains (30), connected to the equipment belonging to the set of collected water equipment.
15. The management process according to any one of claims 12 to 14, characterised in that it comprises a monitoring step (600) of the water network, said monitoring step (600) of the water network comprising the following steps:

    - Definition (610) of at least one standard value of water consumption as a function of time for said facility,

    - Acquisition (620), by the control unit, of a current flow value for each distribution outlet of the sanitary mains,

    - Processing (630) of the current flow values so as to obtain a current value of water consumption as a function of time,

    - Comparison (640) of the current value of water consumption with the standard value of water consumption for the same time period, and

    - Generation (650), if the current value of water consumption exceeds the standard value of water consumption for the same time period, of an unusual consumption alert.

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