EP4403818A1 - Fluid container with dispensing tap with electronic device and independent pressure sensor - Google Patents

Abstract

The invention relates to a container (1) for pressurized fluid, in particular a gas cylinder, comprising a container body (1-1) having an internal volume (2) for keeping a pressurized fluid and equipped with a tap fluid distribution (3). The valve body (3-1) includes an internal fluid circuit (3-2). An electronic device (7) comprises data processing means (5) with a microprocessor (5-1) for processing pressure measurements made by pressure measuring means (4) measuring the pressure of the fluid in the fluid circuit internal (3-2). The pressure measuring means (4) are arranged in the valve body (3-1) in a dissociated manner, that is to say decoupled, from the electronic device (7) by being connected only electrically to the electronic device (7). ) by electrical connection means (20), in particular via a layer comprising several electrical cables arranged in parallel.

Description

The invention relates to a pressurized fluid container, in particular a pressurized gas cylinder, equipped with a fluid distribution valve equipped with an electronic device and a dissociated pressure (and temperature) sensor, c that is to say independent of the electronic device, making it possible to carry out pressure (and temperature) measurements and to supply them to the electronic device, via electrical connection means, such as a layer with several electrical cables.

Medical fluids or gases, such as oxygen, NO/N ₂ , N ₂ O/O ₂ , He/O ₂ , medical air or other mixtures, are packaged in pressurized gas containers, in particular gas cylinders or cylinders, which are equipped with a dispensing valve, also called a valve, with an integrated expansion system (RDI) or without an integrated expansion system, used to provide an adjustable gas flow. Advantageously, a rigid protective covering, also called a “hat”, serves to protect the tap and its fragile equipment against shocks, falls, dirt, etc.

Indeed, the tap or distribution valve can be equipped with an electronic device with a digital display used to display the residual gas pressure in the container or a gas autonomy, that is to say the duration of use before that the container is (almost) empty, as taught by EP-A-2918892 , EP-A-3421866 , US-A-2015/048955 , US-A-6085598 , EP-A-3067665 Or DE-A-3809142

Such an electronic device generally comprises a box embedding one or more (micro)processors carried by a main electronic card and a display screen making it possible to calculate and/or display one or more parameters useful for the user, such as gas flow, gas pressure, autonomy, gas volume or any other parameter. Pressure measuring means are also provided, in particular a pressure sensor or combined pressure and temperature fitted into the housing, that is to say fixed to each other, which are connected to the card. electronic, in particular to the (micro)processor to transmit the pressure measurements which are processed there electronically by one or more microprocessors.

To be able to carry out pressure measurements, the pressure sensor of the electronic device is fluidly connected to the internal gas circuit of the valve which is in fluid communication with the internal volume of the container and which conveys the gas whose pressure and temperature must be measured , typically via a internal channel or "nozzle" passing through the connecting tip used to attach the electronic device to the faucet, as described by EP-A-3421866 . Similar teaching is provided by EP-A-3455547 And FR-A-3091744 .

The fact that the pressure measuring means, typically a pressure sensor and preferably a temperature sensor, are coupled to the electronic device poses maintenance problems for the electronic device. Indeed, it happens that the case, the display screen or another element of the electronic device (i.e. different from the pressure sensor) is faulty or damaged and/or that it no longer functions or malfunctions. In this case, the electronic device must undergo a maintenance operation intended to replace/change it in its entirety, while the pressure measuring means, i.e. the pressure sensor, are still perfectly functional.

During such a maintenance operation, the decoupling of the pressure sensor from the housing to which it is attached, often causes deterioration of the sensor, which is quite fragile, which then makes it non-functional and then requires replacing not only the device electronic but also the sensor attached to it. In addition, such a replacement of the pressure sensor also requires the implementation of a procedure to check the tightness of the new sensor.

We understand that this is not acceptable because it complicates maintenance operations, and is penalizing because the time necessary for maintenance operations and therefore for immobilization of the gas container, is necessarily longer, which generates additional costs.

A problem is therefore to be able to replace the electronic device of a fluid distribution valve, when it is damaged or faulty, without risk or while limiting the risk of deteriorating or damaging the pressure measuring means, typically a pressure (and temperature) sensor, cooperating with this electronic device, when these pressure measuring means, typically this sensor, are still functional, that is to say when they operate normally and do not have to be replaced.

• un corps de robinet comprenant un circuit de fluide interne pour acheminer le fluide sous pression provenant du volume interne du corps de récipient,
• des moyens de mesure de pression configurés pour mesurer au moins la pression du fluide au sein dudit circuit de fluide interne, lesdits moyens de mesure de pression comprenant un capteur de pression raccordé au circuit de gaz interne pour y opérer une ou des mesures de pression et
• un dispositif électronique comprenant des moyens de traitement de données principaux à au moins un microprocesseur principal configurés pour traiter la ou les mesures de pression opérées par les moyens de mesure de pression.

A solution according to the invention then relates to a container of fluid under pressure, in particular a bottle or cylinder of gas under pressure, comprising a container body having an internal volume for keeping a fluid under pressure. pressure, in particular a compressed gas, and equipped with a fluid distribution valve comprising:

• a valve body comprising an internal fluid circuit for conveying pressurized fluid from the internal volume of the container body,
• pressure measuring means configured to measure at least the pressure of the fluid within said internal fluid circuit, said pressure measuring means comprising a pressure sensor connected to the internal gas circuit to carry out one or more pressure measurements and
• an electronic device comprising main data processing means with at least one main microprocessor configured to process the pressure measurement(s) carried out by the pressure measuring means.

• le dispositif électronique comprend un boitier externe rigide, les moyens de traitement de données principaux étant agencés dans le boitier du dispositif électronique,
• les moyens de mesure de pression comprennent des moyens de traitement de données additionnels comprenant au moins un microprocesseur additionnel pour traiter informatiquement les mesures opérées par le capteur de pression et obtenir des mesures traitées, et
• les moyens de mesure de pression sont agencés dans le corps de robinet de manière dissociée du dispositif électronique en étant reliés uniquement électriquement au dispositif électronique par des moyens de liaison électrique comprenant une nappe électrique flexible comprenant au moins 4 fils électriques reliant les moyens de traitement de données additionnels des moyens de mesure de pression aux moyens de traitement de données principaux du dispositif électronique de manière à leur fournir des mesures traitées provenant des moyens de traitement de données additionnels.

In addition, in the container of the invention:

• the electronic device comprises a rigid external casing, the main data processing means being arranged in the casing of the electronic device,
• the pressure measuring means comprise additional data processing means comprising at least one additional microprocessor for computer processing the measurements made by the pressure sensor and obtaining processed measurements, and
• the pressure measuring means are arranged in the valve body in a manner dissociated from the electronic device by being only electrically connected to the electronic device by electrical connection means comprising a flexible electrical cable comprising at least 4 electrical wires connecting the pressure processing means additional data from the pressure measuring means to the main data processing means of the electronic device so as to provide them with processed measurements from the additional data processing means.

In other words, according to the invention, the pressure measuring means are arranged in the valve body and not in the electronic device, that is to say in a manner dissociated from the electronic device, being only electrically connected to said device. electronic by the flexible electrical cable to provide it with the measurements taken.

• les moyens de mesure de pression comprennent un capteur de pression raccordé au circuit de gaz interne pour y opérer la ou les mesures de pression.
• de préférence, les moyens de mesure de pression comprennent un capteur combiné de pression et de température configuré pour opérer des mesures de pression et de température du fluide.
• la nappe comprend de 4 à 20 fils électriques (i.e. des câbles fins) agencés en parallèle les uns des autres, i.e. des fils, câbles ou analogues.
• la nappe comprend de 4 à 15 fils électriques agencés en parallèle les uns des autres.
• les moyens de mesure de pression sont agencés dans un logement à capteur aménagé dans le corps de robinet.
• le logement à capteur aménagé dans le corps de robinet comprend un fond.
• le logement à capteur aménagé dans le corps de robinet est ouvert vers l'extérieur.
• le logement à capteur communique fluidiquement avec le circuit de fluide interne du corps de robinet, de préférence via un port de mesure aménagé dans le fond du logement à capteur.
• les moyens de mesure de pression comprennent au moins une carte électronique additionnelle.
• ladite au moins une carte électronique additionnelle comprend ledit au moins un microprocesseur additionnel servant à traiter informatiquement les mesures opérées par le capteur de pression et obtenir des mesures traitées.
• les moyens de traitement de données additionnels comprennent un ou plusieurs microprocesseurs additionnels.
• la nappe électrique relie les moyens de traitement de données additionnels aux moyens de traitement de données principaux du dispositif électronique de manière à fournir au moyens de traitement de données du dispositif électronique, la ou les mesures traitées provenant du ou des microprocesseur(s) additionnel(s) des moyens de traitement de données additionnels.
• les moyens de traitement de données principaux sont configurés pour déterminer une pression de gaz résiduelle ou une autonomie en gaz par traitement des mesures de pression ou de pression et de température, fournies par les moyens de mesure de pression, en particulier par le microprocesseur additionnel.
• les moyens de traitement de données principaux du dispositif électronique comprennent au moins un microprocesseur principal, de préférence agencé sur une carte électronique principale.
• le circuit de gaz interne est agencé dans le corps de robinet et s'étend entre un orifice d'entrée de fluide en communication fluidique avec le volume interne du corps de récipient et au moins un orifice de sortie de fluide porté par un embout de distribution de fluide.
• la nappe électrique flexible est souple et déformable, pour faciliter les branchements et sa mise en place.
• la nappe électrique flexible comprend un matériau souple de type polymère ou tout autre matériau adapté.
• la nappe comprend à ses extrémités libres des connecteurs de raccordement électrique configurés pour permettre le raccordement de la nappe aux moyens de mesure de pression, d'une part, et au dispositif électronique, d'autre part.
• les moyens de mesure de pression et le dispositif électronique comprennent des connecteurs de raccordement électrique complémentaires de ceux de la nappe.
• les connecteurs de raccordement électrique complémentaires sont agencés sur le capteur de pression (et de température) et sur les moyens de traitement de données principaux du dispositif électronique, en particulier sur la carte électronique additionnelle et sur la carte électronique principale.
• le dispositif électronique comprend un afficheur numérique pour afficher la pression de gaz résiduelle et/ou l'autonomie en gaz déterminées par les moyens de traitement de données principaux du dispositif électronique.

Depending on the embodiment considered, the pressurized fluid container of the invention may comprise one or more of the following characteristics:

• the pressure measuring means comprise a pressure sensor connected to the internal gas circuit to carry out the pressure measurement(s).
• preferably, the pressure measuring means comprise a combined pressure and temperature sensor configured to carry out pressure and temperature measurements of the fluid.
• the sheet comprises 4 to 20 electrical wires (ie fine cables) arranged in parallel to each other, ie wires, cables or the like.
• the sheet comprises 4 to 15 electrical wires arranged in parallel to each other.
• the pressure measuring means are arranged in a sensor housing arranged in the valve body.
• the sensor housing arranged in the faucet body comprises a bottom.
• the sensor housing in the faucet body is open to the outside.
• the sensor housing communicates fluidly with the internal fluid circuit of the valve body, preferably via a measurement port provided in the bottom of the sensor housing.
• the pressure measuring means comprise at least one additional electronic card.
• said at least one additional electronic card comprises said at least one additional microprocessor used to computer-process the measurements made by the pressure sensor and obtain processed measurements.
• the additional data processing means comprise one or more additional microprocessors.
• the electrical cable connects the additional data processing means to the main data processing means of the electronic device so as to provide the data processing means of the electronic device with the processed measurement(s) coming from the additional microprocessor(s) s) additional data processing means.
• the main data processing means are configured to determine a residual gas pressure or a gas autonomy by processing the pressure or pressure and temperature measurements, provided by the pressure measuring means, in particular by the additional microprocessor.
• the main data processing means of the electronic device comprise at least one main microprocessor, preferably arranged on a main electronic card.
• the internal gas circuit is arranged in the valve body and extends between a fluid inlet orifice in fluid communication with the internal volume of the container body and at least one fluid outlet orifice carried by a distribution tip of fluid.
• The flexible electrical cable is flexible and deformable, to facilitate connections and installation.
• the flexible electrical cable comprises a flexible polymer type material or any other suitable material.
• the sheet comprises at its free ends electrical connection connectors configured to allow the connection of the sheet to the pressure measuring means, on the one hand, and to the electronic device, on the other hand.
• the pressure measuring means and the electronic device comprise electrical connection connectors complementary to those of the tablecloth.
• the complementary electrical connection connectors are arranged on the pressure (and temperature) sensor and on the main data processing means of the electronic device, in particular on the additional electronic card and on the main electronic card.
• the electronic device comprises a digital display for displaying the residual gas pressure and/or the gas autonomy determined by the main data processing means of the electronic device.

• le dispositif électronique comprend ledit au moins un microprocesseur principal agencé sur une carte électronique principale.
• le capteur de pression et éventuellement de température est connecté électriquement aux moyens de traitement de données additionnels pour fournir des mesures (i.e. signaux) de pression et de température du fluide auxdits moyens de traitement de données additionnels.
• le capteur de pression et de température est configuré pour mesurer des températures comprises entre -40°C et +70°C et des pressions comprises entre 0 et au moins 150 bar abs, de préférence au moins 250 bar abs.
• le capteur de pression et de température comprend un corps de capteur traversé par un passage interne permettant de mesurer la pression et la température, c'est-à-dire constituant un piquage unique de prise de pression et de température.
• les moyens de traitement de données principaux du dispositif électronique, en particulier le (ou les) microprocesseur principal, sont configurés pour traiter la ou les mesures de pression et de température.
• le (ou les) microprocesseur(s) principal met en oeuvre un ou plusieurs algorithmes.
• les moyens de traitement de données principaux du dispositif électronique comprennent au moins un microcontrôleur. Plus précisément, un (ou plusieurs) microprocesseur principal peut être intégré au dispositif électronique sous forme d'un microcontrôleur.
• le (ou les) microprocesseur(s) principal, en particulier le (ou les) microcontrôleur, est configuré pour enregistrer des données, notamment au sein d'un logiciel ou algorithme dédié.
• le capteur unique de pression et de température est en communication fluidique avec le circuit de gaz interne du robinet de distribution de fluide de manière à permettre d'opérer les mesures de pression et de température du gaz véhiculé par ledit circuit interne, c'est-à-dire au sein du passage interne de gaz du robinet de distribution de gaz, ledit passage interne étant en communication fluidique avec le volume interne du récipient de gaz.
• les moyens de traitement de données, en particulier le(s) microprocesseur, principal est alimenté en courant électrique par une source de courant électrique.
• le capteur unique de pression et de température, en particulier les moyens de traitement de données additionnels dudit capteur, est alimenté en courant électrique par une source de courant électrique.
• le capteur unique de pression et de température comprend des moyens de traitement de données additionnels ou électronique embarquée additionnelle permettant de déterminer la pression et la température du gaz.
• les moyens de traitement de données additionnels coopèrent avec des moyens à membrane pour déterminer la pression du gaz et des moyens à sonde de température pour mesurer la température du gaz.
• les moyens à membrane et les moyens à sonde de température sont agencés de manière à être en contact avec le gaz véhiculé par le passage interne du corps de capteur, c'est-à-dire un seul et même conduit de gaz.
• les moyens de traitement de données additionnels, c'est-à-dire l'électronique embarquée du capteur de pression et de température, sont connectés électriquement aux moyens de traitement de données du dispositif électronique pour leur communiquer des signaux et/ou des valeurs de pression et de température mesurées, en particulier via la nappe.
• le dispositif électronique est un manomètre digital configuré pour fournir la pression de gaz ou le volume de gaz dans le récipient, le débit de gaz fourni par le robinet et/ou l'autonomie, i.e. durée d'utilisation par rapport à la quantité de fluide résiduel dans le récipient et/ou au débit de fourniture du gaz par le robinet.
• la source de courant électrique comprend une ou plusieurs batteries ou piles électriques, rechargeables ou non.
• le dispositif électronique comprend un afficheur numérique, i.e. tel un écran d'affichage d'information, par exemple de type LCD.
• le récipient de fluide sous pression comprend un volume interne de stockage de fluide sous pression, en particulier de gaz sous pression.
• le robinet de distribution de fluide comprend un dispositif de sélection de débit permettant de sélectionner un débit de fluide désiré, de préférence compris entre 0 et 30 L/min.
• le robinet de distribution de fluide comprend un raccord de sortie en débit pour délivrer le fluide au débit désiré, typiquement un gaz.
• le raccord de sortie comprend, des moyens de contrôle de la sortie de gaz.
• le robinet de distribution de fluide comprend un orifice d'entrée de fluide en communication fluidique avec le circuit de gaz interne du robinet de distribution de fluide de manière à permettre l'entrée de fluide sous pression dans le circuit de gaz interne du robinet de distribution de fluide.
• l'orifice d'entrée de fluide du robinet de distribution de fluide est en communication fluidique avec le volume interne du récipient de fluide.
• le circuit de gaz interne du robinet de distribution de fluide relie fluidiquement l'orifice d'entrée de fluide au raccord de sortie en débit.
• le circuit de gaz interne du robinet de distribution de fluide est aménagé, par exemple percé, dans le corps du robinet de distribution de fluide.
• le raccord de sortie en débit du robinet de distribution de fluide est configuré pour être connecté fluidiquement à une conduite de gaz flexible ou un autre dispositif utilisant le fluide, tel un dispositif ou appareil médical.
• le dispositif électronique comprend un boitier externe rigide, par exemple en métal ou en polymère.
• les moyens de traitement de données sont agencés dans le boitier du dispositif électronique.
• le dispositif électronique est un manomètre digital permettant de déterminer une pression et/ou un volume de fluide et/ou une autonomie, de préférence en gaz.
• le dispositif de sélection de débit comprend un volant rotatif configuré pour se déplacer entre plusieurs positions angulairement décalées les uns des autres, chaque position correspondant à une valeur de débit de gaz désiré donnée.
• le dispositif de sélection de débit permet de sélectionner des débits de gaz désirés compris entre 0 et 30 L/min, typiquement entre 0 et 25 L/min.
• le dispositif de sélection de débit coopère en outre avec un dispositif de réglage de débit agencé dans le corps du robinet afin de régler le débit à la valeur de débit de gaz désiré.
• le dispositif de réglage de débit comprend un disque à orifices calibré agencé sur le trajet du gaz dans le corps du robinet.
• le raccord de sortie de gaz est agencé au centre du volant rotatif, c'est-à-dire qu'ils sont agencés coaxialement l'un à l'autre.
• les moyens de traitement de données comprennent un compteur temporel.
• le récipient a un volume interne compris entre 1 et 20 L, typiquement entre 2 et 15 L (équivalent en eau).
• l'afficheur numérique du dispositif électronique est configuré pour afficher des informations, en particulier une autonomie en gaz, une pression de gaz, un volume de gaz ou une icône d'alerte, par exemple d'alerte d'autonomie ou de clampage de tuyau, ou autres.
• les moyens de traitement de données sont configurés pour déclencher une alerte sonore et une alerte visuelle en cas de déclenchement d'une alerte, notamment une alerte de clampage ou d'une alerte d'autonomie.
• Il comprend en outre des moyens de mémorisation de données.
• les moyens de mémorisation de données comprennent une mémoire morte, de préférence une EEPROM ou analogue.
• les moyens de mémorisation de données sont agencés sur une carte électronique, de préférence sur la carte électronique principale portant le microprocesseur principal.
• le dispositif électronique est fixé au corps du robinet de distribution de gaz, notamment par vissage ou par un système à goupille.
• la source d'énergie électrique alimente électriquement les moyens de traitement de données principaux, typiquement la carte électrique principale, le (ou les) microprocesseurs, et tous les composants fonctionnant avec du courant électrique, comme l'afficheur numérique, le capteur de pression et de température et/ou une LED d'alerte.
• le robinet de distribution de fluide est protégé par un capotage de protection comprenant un corps de capotage rigide agencé autour dudit robinet de distribution de fluide.
• la source de courant électrique est agencé dans un compartiment du capotage de protection.
• le boîtier du dispositif électronique comprenant l'afficheur numérique est logé dans une ouverture aménagée dans le corps de capotage.
• le corps de capotage définit un volume interne dimensionné pour loger le robinet de distribution de gaz.
• le corps de capotage est en matériau polymère, en métal ou leurs combinaisons.
• le corps de capotage comprend une (ou plusieurs) poignée de portage, de préférence la poignée de portage est agencée de manière à surmonter le capotage, c'est-à-dire qu'elle est située sensiblement au-dessus du capotage.
• le robinet de distribution de gaz est un robinet à détendeur intégré ou RDI.
• des moyens de détente de gaz sont agencés sur le circuit interne de gaz.
• les moyens de détente de gaz comprennent un clapet de détente et un siège de clapet. Ils permettant de réduire la pression du gaz depuis la pression haute du gaz stocké dans le récipient, typiquement plusieurs dizaines à centaines de bar, jusqu'à une pression d'utilisation préfixée plus basse, typiquement de quelques bar, par exemple de 2 à 5 bar abs.
• le robinet de distribution de fluide est en alliage de cuivre, tel du laiton.
• le corps de capotage comprend en outre un système d'accrochage conçu pour permettre son accrochage à un support, en particulier à un barreau de lit d'hôpital ou à un brancard de transport de patient ou analogue.
• le corps de capotage comprend en outre un système d'accrochage mobile, de préférence pivotant.
• le récipient de fluide est une bouteille de gaz sous pression.
• le récipient de fluide contient un gaz sous pression, en particulier un gaz médical.
• le récipient de fluide contient, lorsqu'il est plein, un gaz à une pression d'au moins 130 à 200 bar abs, voire d'au moins 300 bar abs.
• le récipient de fluide a une forme générale cylindrique, en particulier d'ogive, en métal ou alliage métallique (e.g. acier, aluminium....) ou en matériau(x) composite(s).
• le récipient de fluide contient un gaz ou mélange gazeux, tel de l'oxygène, un mélange NO/N₂, O₂/N₂O ou He/O₂, de l'air ou autre.

Furthermore, according to the embodiment considered, the pressurized fluid container of the invention and/or the valve of the invention fitted to said container may comprise one or more of the following characteristics:

• the electronic device comprises said at least one main microprocessor arranged on a main electronic card.
• the pressure and possibly temperature sensor is electrically connected to the additional data processing means to provide measurements (ie signals) of pressure and temperature of the fluid to said additional data processing means.
• the pressure and temperature sensor is configured to measure temperatures between -40°C and +70°C and pressures between 0 and at least 150 bar abs, preferably at least 250 bar abs.
• the pressure and temperature sensor comprises a sensor body crossed by an internal passage making it possible to measure the pressure and the temperature, that is to say constituting a single tap for taking pressure and temperature.
• the main data processing means of the electronic device, in particular the main microprocessor(s), are configured to process the pressure and temperature measurement(s).
• the main microprocessor(s) implements one or more algorithms.
• the main data processing means of the electronic device comprise at least one microcontroller. More specifically, one (or more) main microprocessor can be integrated into the electronic device in the form of a microcontroller.
• the main microprocessor(s), in particular the microcontroller(s), is configured to record data, in particular within dedicated software or algorithm.
• the single pressure and temperature sensor is in fluid communication with the internal gas circuit of the fluid distribution valve so as to allow pressure and temperature measurements of the gas conveyed by said internal circuit to be carried out, i.e. that is to say within the internal gas passage of the gas distribution valve, said internal passage being in fluid communication with the internal volume of the gas container.
• the data processing means, in particular the main microprocessor(s), is supplied with electric current by an electric current source.
• the single pressure and temperature sensor, in particular the additional data processing means of said sensor, is supplied with electric current by an electric current source.
• the single pressure and temperature sensor includes additional data processing means or additional on-board electronics making it possible to determine the pressure and temperature of the gas.
• the additional data processing means cooperate with membrane means to determine the pressure of the gas and temperature probe means to measure the temperature of the gas.
• the membrane means and the temperature probe means are arranged so as to be in contact with the gas conveyed by the internal passage of the sensor body, that is to say a single gas conduit.
• the additional data processing means, that is to say the on-board electronics of the pressure and temperature sensor, are electrically connected to the data processing means of the electronic device to communicate to them signals and/or values of pressure and temperature measured, in particular via the water table.
• the electronic device is a digital pressure gauge configured to provide the gas pressure or the volume of gas in the container, the gas flow rate supplied by the tap and/or the autonomy, ie duration of use in relation to the quantity of fluid residual in the container and/or at the gas supply flow rate through the tap.
• the source of electric current comprises one or more batteries or electric cells, rechargeable or not.
• the electronic device comprises a digital display, ie such as an information display screen, for example of the LCD type.
• the pressurized fluid container comprises an internal volume for storing pressurized fluid, in particular pressurized gas.
• the fluid distribution valve comprises a flow selection device making it possible to select a desired fluid flow rate, preferably between 0 and 30 L/min.
• the fluid dispensing valve includes a flow outlet connection for delivering the fluid at the desired flow rate, typically a gas.
• the outlet connection comprises means for controlling the gas outlet.
• the fluid dispensing valve includes a fluid inlet port in fluid communication with the internal gas circuit of the fluid dispensing valve so as to permit entry of pressurized fluid into the internal gas circuit of the dispensing valve of fluid.
• the fluid inlet port of the fluid dispensing valve is in fluid communication with the internal volume of the fluid container.
• the internal gas circuit of the fluid dispensing valve fluidly connects the fluid inlet port to the flow outlet fitting.
• the internal gas circuit of the fluid distribution valve is arranged, for example drilled, in the body of the fluid distribution valve.
• the flow outlet fitting of the fluid dispensing valve is configured to be fluidly connected to a flexible gas line or other device using the fluid, such as a medical device or apparatus.
• the electronic device comprises a rigid external casing, for example made of metal or polymer.
• the data processing means are arranged in the housing of the electronic device.
• the electronic device is a digital pressure gauge making it possible to determine a pressure and/or a volume of fluid and/or an autonomy, preferably in gas.
• the flow selection device comprises a rotary wheel configured to move between several positions angularly offset from each other, each position corresponding to a given desired gas flow value.
• the flow selection device makes it possible to select desired gas flow rates of between 0 and 30 L/min, typically between 0 and 25 L/min.
• the flow selection device further cooperates with a flow adjustment device arranged in the body of the valve in order to adjust the flow rate to the desired gas flow value.
• the flow adjustment device comprises a calibrated orifice disc arranged on the gas path in the valve body.
• the gas outlet connection is arranged in the center of the rotating flywheel, that is to say, they are arranged coaxially with each other.
• the data processing means include a time counter.
• the container has an internal volume of between 1 and 20 L, typically between 2 and 15 L (water equivalent).
• the digital display of the electronic device is configured to display information, in particular a gas autonomy, a gas pressure, a gas volume or an alert icon, for example of autonomy alert or pipe clamping , or others.
• the data processing means are configured to trigger an audible alert and a visual alert in the event of triggering an alert, in particular a clamping alert or an autonomy alert.
• It further includes data storage means.
• the data storage means comprise a read-only memory, preferably an EEPROM or the like.
• the data storage means are arranged on an electronic card, preferably on the main electronic card carrying the main microprocessor.
• the electronic device is fixed to the body of the gas distribution valve, in particular by screwing or by a pin system.
• the electrical energy source electrically supplies the main data processing means, typically the main electrical card, the microprocessor(s), and all the components operating with electric current, such as the digital display, the pressure sensor and temperature and/or an alert LED.
• the fluid distribution valve is protected by a protective covering comprising a rigid covering body arranged around said fluid distribution valve.
• the source of electric current is arranged in a compartment of the protective covering.
• the housing of the electronic device comprising the digital display is housed in an opening provided in the cowling body.
• the cover body defines an internal volume dimensioned to accommodate the gas distribution valve.
• the cowling body is made of polymer material, metal or combinations thereof.
• the cowling body comprises one (or more) carrying handle, preferably the carrying handle is arranged so as to overcome the cowling, that is to say that it is located substantially above the cowling.
• The gas distribution valve is an integrated regulator valve or RDI.
• gas expansion means are arranged on the internal gas circuit.
• the gas expansion means includes an expansion valve and a valve seat. They make it possible to reduce the gas pressure from the high pressure of the gas stored in the container, typically several tens to hundreds of bars, to a lower preset operating pressure, typically a few bars, for example from 2 to 5 bar abs.
• the fluid distribution valve is made of copper alloy, like brass.
• the covering body further comprises a hooking system designed to allow it to be hooked to a support, in particular to a hospital bed bar or to a patient transport stretcher or the like.
• the cowling body further comprises a movable, preferably pivoting, attachment system.
• the fluid container is a pressurized gas cylinder.
• the fluid container contains a gas under pressure, in particular a medical gas.
• the fluid container contains, when full, a gas at a pressure of at least 130 to 200 bar abs, or even at least 300 bar abs.
• the fluid container has a generally cylindrical shape, in particular a conical shape, made of metal or metal alloy (eg steel, aluminum, etc.) or of composite material(s).
• the fluid container contains a gas or gas mixture, such as oxygen, a NO/N ₂ , O ₂ /N ₂ O or He/O ₂ mixture, air or the like.

The invention also relates to a use of a container according to the invention for storing or supplying a gas under pressure, in particular a medical gas chosen from oxygen or a gas mixture N ₂ O/O ₂ , NO/N ₂ , He/O ₂ , medical air or another medical gas.

• Fig. 1 est un schéma de principe d'un récipient de fluide équipé d'un robinet de distribution de gaz à dispositif électronique,
• Fig. 2 représente un mode de réalisation d'un récipient de fluide 1 de type bouteille de gaz sous pression,
• Fig. 3 est un schéma (vue de face) d'un mode de réalisation d'une partie d'un robinet de distribution de gaz à dispositif électronique selon l'invention,
• Fig. 4 est un schéma (vue de 3/4) d'une partie du robinet de Fig. 3,
• Fig. 5 est une vue schématique en coupe du robinet de Fig. 3 et Fig. 4, et
• Fig. 6 est un schéma en coupe du capteur de pression équipant le robinet de Fig. 3 à Fig. 5.

The invention will now be better understood thanks to the following detailed description, given by way of illustration but not limitation, with reference to the appended figure, namely:

• Fig. 1 is a schematic diagram of a fluid container equipped with a gas distribution valve with an electronic device,
• Fig. 2 represents an embodiment of a fluid container 1 of the pressurized gas bottle type,
• Fig. 3 is a diagram (front view) of an embodiment of a part of a gas distribution valve with an electronic device according to the invention,
• Fig. 4 is a diagram (3/4 view) of part of the faucet Fig. 3 ,
• Fig. 5 is a schematic sectional view of the faucet Fig. 3 And Fig. 4 , And
• Fig. 6 is a sectional diagram of the pressure sensor fitted to the valve Fig. 3 to Fig. 5 .

Fig. 1 is a schematic diagram of a container of fluid 1 under pressure, while the Fig. 2 represents an embodiment of such a fluid container 1, namely here a pressurized gas cylinder with axis AA.

The fluid container 1 comprises a container body 1-1 delimiting an internal volume 2 designed to allow the storage of a pressurized fluid, typically a pressurized gas, for example medical gas, at a pressure (i.e. filled container) greater than 100 bar abs, typically at least 150 bar abs, or even more than 200 bar abs, typically a maximum pressure ranging from 130 to 300 bar abs. The container body 1-1 is generally made of metal or metal alloy, such as steel or an aluminum alloy, or of composite materials.

The container body 1-1 carries a fluid distribution valve 3, preferably an RDI, that is to say a valve with an integrated regulator, crossed by an internal fluid circuit in fluid communication with the internal volume 2 of the container 1.

The valve body 3-1 is preferably made of brass or stainless steel. The internal fluid circuit (not visible) which comprises one or more gas passages arranged in the container body 1-1, for example drilled or machined, connects and extends between a fluid inlet orifice in fluid communication with the internal volume 2 of the container body 1-1 and one (or more) fluid outlet orifice carried by one (or more) fluid distribution nozzles 11 (cf. Fig. 2 , such as a flow outlet connection. This fluid circuit conveys the fluid, namely here gas, coming from the container 1 through the body of the gas distribution valve 3 to the fluid distribution nozzle 11 to which a gas pipe is usually fluidly connected. flexible (not shown) used to convey the gas to another device (not shown) using the gas, that is to say a medical device or device using the gas supplied by the tap 3, for example a respiratory mask distributing gas to a patient at a rate prescribed by a doctor or the like corresponding to a treatment to be followed.

The AA axis gas bottle or container 1 Fig. 2 comprises a container body 1-1 of generally cylindrical shape comprising a neck, at its upper end carrying the tap 3, that is to say it is in the shape of an ogive. The neck includes the fluid outlet orifice communicating with the internal volume 2 of the container 1 and making it possible to withdraw the gas from the internal volume 2 or, conversely, to fill it when it is empty. The gas distribution valve 3 is mounted, typically screwed, at the level of the orifice in the neck of the gas bottle 1.

The fluid stored in the container 1, ie stored in its internal volume 2, is typically a gas or gas mixture, for example of medical quality (ie a medical gas), such as oxygen, air, a NO/ mixture. N ₂ , O ₂ /N ₂ O or He/O ₂ , or any other gas or gas mixture.

The gas distribution valve 3 comprises pressure measuring means 4 making it possible to measure (at least) the gas pressure within the internal circuit 3-2 of the valve body 3-1, as illustrated in Fig. 5 . They typically include a pressure sensor 4-1 having a pressure tap 41, that is to say a tap, fluidly connected to the internal circuit 3-2 of the valve body 3-1, as shown schematically in Fig. 6 .

Advantageously, a combined 4-1 pressure and temperature sensor is used to measure both the pressure and the temperature of the gas, within the internal gas circuit 3-2 conveying the gas coming from the internal volume 2 of the container 1. It is configured to measure temperatures between -40°C and +70°C and pressures between 0 and at least 150 bar abs.

The pressure measuring means 4 and preferably temperature measuring means are configured to provide measurements (ie measurement signals or values) of pressure and preferably temperature to main microprocessor data processing means 5 comprising one or more microprocessors 5-1 main implementing one or more algorithms, for example a main electronic card carrying one (or more) main 5-1 microprocessor implementing one or more calculation algorithms or the like, preferably a microcontroller, as shown schematically in Fig. 1 .

More precisely, the pressure and optionally temperature measurements or data carried out by the sensor 4-1 are processed by on-board electronics within the sensor 4-1, for example an additional or secondary electronic card with additional microprocessor(s) or the like. .

Then, these measurements (i.e. signals or values) or data are sent to the main data processing means 5 comprising the main microprocessor 5-1 in order to be used there, i.e. computer processed, in particular to determine, calculate or deduce a pressure or gas autonomy.

A time counter internal to the main data processing means 5 can also be provided.

The main data processing means 5 are arranged in the external housing 7-1 of an electronic device 7, for example a digital pressure gauge, attached to the fluid distribution valve 3. The electronic device 7 also includes display means 6, such as a digital display, for example an LCD screen or the like, used to display different information, such as the volume or pressure of gas in the container 1 or even the gas autonomy (in hours and minutes for example), which are obtained in particular by processing pressure and/or temperature measurements by the main data processing means 5, or even displaying an alarm message. For example, the digital display 6 comprises a screen with a height of between approximately 29 and 37 mm and a width, for example between approximately 39 and 43 mm.

The housing 7-1 of the electronic device 7 can be made of polymer or metal.

It is also possible to provide, on the box 7-1, one or more buttons 8 or selection keys which can be activated by digital pressure from the user to make choices, scroll through a menu(s), acknowledge an alarm or other .

The internal volume 2 of the container 1 (in water equivalent) is a known value which can be memorized by storage means 9, such as an EEPROM type computer memory, of the electronic device 7. For example, gas bottles used to distribute medical oxygen (i.e. medical grade) have volumes between 1 L and 20 L (water equiv.), typically between 2 L and 15 L, for example, depending on the bottle considered, the volume can be order of 2 L, 3.5 L, 4.6 L, 5 L, 7 L, 10 L, 11 L or 15 L.

The storage means 9 can also record other data, such as for example the time elapsed between successive instants, pressure and/or temperature measurements, etc. or other parameters, such as the position of the selector, bottle configuration, filling pressure, alerts...

More generally, the electronic device 7, for example a digital pressure gauge, which comprises the main data processing means 5 with a main microprocessor 5-1, such as a main electronic card, is housed in an opening or housing provided in the body 10 of the protective covering 13 arranged around the fluid distribution valve 3 and serving to protect it against shocks or other possible damage, for example a rigid covering made of polymer and/or metal, as illustrated in Fig. 2 .

The body 10 of the cowling 13 defines an internal volume dimensioned to accommodate the gas distribution valve, namely here a valve with an integrated regulator or RDI, and also comprises one (or more) carrying handle 16 arranged here so as to overcome the cowling 13, that is to say that it is located substantially above the body 10 of the cowling 13, being connected to the body 10 by here two support posts 17 projecting substantially upwards. The cowling body 10 may further comprise a hooking system 18 (not completely visible), preferably a pivoting hook, designed to allow it to be hooked to a support, in particular to a hospital bed bar or to a stretcher. patient transport or the like.

The electronic device 7 is electrically powered by a source of electrical energy (not visible) arranged in the cowling 13, for example one or batteries or cells arranged in a battery housing arranged in the wall of the cowling body and closed by a removable hatch or the like.

The source of electrical energy serves to power the components of the electronic device 7 requiring electric current to operate, in particular the main data processing means 5 with main microprocessor 5-1, the display screen 6, the memory 9 ... The source of electrical energy is connected to the electronic device 7 by electrical connections, for example wires or the like.

The main data processing means 5 are also configured to control audible alert means and/or visual alert means, preferably both, so as to trigger at least one audible alert and/or one visual alert, preferably both, in the event of detection of a malfunction, in particular a clamping, or a quantity of gas or autonomy that is too low.

As illustrated in Fig. 2 And Fig. 4 , a flow selection device 12 operable by a user, such as a rotary steering wheel, carried by the valve body 3-1 serves to select a desired gas flow rate to be delivered by the outlet nozzle 11, for example a steering wheel rotary which can move in rotation between several angular positions, offset from each other, which each correspond to a given flow value, for example selectable gas flow values between 0 L/min and 30 L/min, typically between 0 and 25 L/min. For example, the selectable flow values can be: 0, 0.5, 1, 2, 3, 5, 8, 10, 12, 15, 20, 22 and 25 L/min, or any other value.

Here, the desired flow rate value selected by the user by actuation of the flow selection device 12 appears in a reading window 14 located above the flow selection device 12, for example a cutout made in the body 10 of the protective covering 13 arranged around the valve 3 and serving to protect it against shocks or other external attacks.

The flow selection device 12 further cooperates with a flow adjustment device (not visible) arranged in the valve body 3-1 in order to adjust the flow rate to the desired gas flow value, for example the adjustment device flow rate can be a calibrated orifice disc arranged on the path of the gas in the body of the valve 3. Such an arrangement is known per se.

Once the desired gas flow rate has been selected, the position of the flow selection device 12, for example the angular position of the rotary wheel, can be determined using one (or more) position sensor(s) 19 visible in Fig. 3 , which is electrically connected to the data processing means 5 of the electronic device 7 to provide them with position information. This then allows the data processing means 5 which process position information to know the value of the desired gas flow having been selected by the user.

In the embodiment of the Fig. 2 , the flow outlet connection 11 is arranged in the center and coaxially with the rotary flow selection wheel 12; however, they could also be separated from each other according to other possible embodiments (not shown). The flow outlet connection 11 carries a gas distribution orifice 11-1, which constitutes an outlet of the internal passage 3-2 of the valve body 3-1.

Preferably, as visible in Fig. 5 , the flow outlet nozzle or connector 11 comprises, upstream of the outlet orifice 11-1, gas outlet control means 11-2, typically a valve movable axially in the connector 11 and cooperating with a valve seat, sealing means, such as one or more O-rings, and an elastic means, such as a spring or the like, normally pushing the valve against the seat to ensure a gas seal when gas is not drawn off, ie distributed.

According to the invention, as illustrated in Fig. 3 , it must be possible to replace the electronic device 7 fixed to the body 3-1 of the valve 3 for distributing fluid, ie gas, when it is damaged or faulty, without risk or while limiting the risk of deteriorating or damaging the means pressure measuring device 4, typically a pressure or pressure and temperature sensor 4-1, cooperating with this electronic device 7, when these pressure measuring means 4 are still functioning normally and do not have to be replaced.

To do this, according to the invention, the pressure measuring means 4, typically a pressure sensor 4-1, preferably pressure and temperature, are arranged on or in the valve body 3-1 in a manner dissociated from the electronic device 7 by being connected only electrically to the electronic device 7 by electrical connection means 20, as illustrated in Fig. 3 to Fig. 5 .

As seen on Fig. 3 to Fig. 5 , according to the invention, the pressure measuring means 4 are not directly interposed/fixed between the electronic device 7 and the valve body 3-1, but are arranged in a specific housing or sensor housing 21, machined in the body of the valve 3-2, which opens, that is to say is open (at 21-2), at the level of the external peripheral surface of the body of the valve 3-2 in order to be able to arrange there the means for measuring the pressure 4.

Furthermore, the sensor housing 21 communicates fluidly, at its bottom 21-1, via a measurement port 22, with the internal gas circuit 3-2 in order to allow pressure measurements and preferably of gas temperature. The measurement port 22 is arranged in the bottom 21-1 of the sensor housing 21.

The pressure measuring means 4, ie the additional electronics embedded in the sensor 4-1, comprising additional data processing means 42 with additional microprocessor(s) 4-7, are electrically connected to the processing means main data 5 of the electronic device 7, typically another main electronic card(s) comprising a main microprocessor(s), by electrical connection means 20 of the electrical cable type 20-1, as illustrated in Fig. 5 .

The electrical cable 20-1 is connected via a first end 20-1A to the data processing means 5 of the electronic device 7 and via a second end 20-1B to the pressure measuring means 4, typically to a cable connector 4 -7 of sensor 4-1 which is arranged in sensor housing 21.

Such an electrical cable 20-1, also called a ribbon cable or the like, comprises several fine electrical wires or cables, that is to say of small dimension/section, arranged in parallel to each other and fixed to each other. so as to form a ribbon or a small strip of cables, for example between 2 and 20 cables, typically from 4 to 15 cables.

The 20-1 electrical cable is flexible. In order to facilitate its connection to the sensor 4-1 and to the electronic device 7, its ends 20-1A, 20-1B are preferably provided with electrical connectors, such as connection strips or the like. It may be formed from polymer or the like.

Fig. 6 is a sectional diagram of an embodiment of the pressure sensor 4-1 and temperature of the pressure measuring means 4. It comprises a sensor body 40 crossed by an internal passage 41, for example an axial passage, c that is to say a single conduit or connection. The internal passage 41 is fluidly connected to the internal gas circuit 3-2 passing through the body 3-1 of the fluid distribution valve 3 so that part of the pressurized gas (arrow G) conveyed by the internal circuit of gas 3-2 fills this internal passage 41 in order to allow the desired pressure and temperature measurements to be carried out.

To do this, membrane means 4-4 can be used, such as a flexible membrane, and temperature probe means 4-5, such as a temperature probe. For example, the membrane can be arranged in contact with the gas conveyed by the internal passage 41 to measure the pressure of the gas and the temperature probe can be arranged, for example behind the membrane, to measure the temperature of the gas supplied by the passage internal 41. The measurements taken, i.e. the data, can be provided and processed by an additional microprocessor 4-6. All of these elements can be arranged on a secondary electronic card 4-3 so as to constitute all or part of the on-board electronics of the sensor 4-1, that is to say the additional data processing means 42 .

We see that the secondary electronic card 4-3 can also carry a cable connector 4-7 in order to allow the electrical connection of the cable 20-1.

The pressure measuring means 4 comprise a cover or cap 44, serving to protect the fragile components of the sensor 4, typically the additional data processing means 42.

In other words, according to the invention, we have therefore decoupled the pressure measurement function (and preferably temperature) from the data display function 5 operated by the electronic device 7, which greatly facilitates any maintenance operations.

Indeed, the pressure measuring means 4, typically the pressure sensor 4-1, are no longer coupled or attached directly to the electronic device 4 but fixed to the valve body 3-1 in a dissociated manner from the electronic device 7, it that is to say at a distance from the latter by being arranged in a sensor housing 21 machined, for example drilled, in the valve body 3-1 and connected to the means of data processing 5 of the electronic device 7 via one or more connection cables, that is to say the tablecloth 20-1 comprising several fine cables grouped together and equipped at its ends 20-1A, 20-1B with connectors at their ends .

It is therefore sufficient to simply disconnect the cable 20-1 connecting the pressure (and temperature) sensor 4-1, in particular the additional data processing means 42, to the electronic device 7, via the connectors of the cable 20- 1, to carry out the required maintenance, that is to say the replacement of the electronic device 7 without having to also dismantle the sensor 4-1.

Electrical connection connectors complementary to those of the tablecloth 20-1 are arranged on the pressure sensor 4-1 or the additional data processing means 42, such as the additional electronic card, and in the electronic device 7, in particular on the main electronic card, to allow the connectors located at the ends 20-1A, 20-1B of the tablecloth 20-1 to be connected.

Thanks to the use of such a sheet 20-1, there is therefore no or no more risk of damaging the pressure sensor 4-1 or its assembly, nor of causing an untimely leak. It is therefore no longer necessary to check the tightness between sensor 4-1 and valve body 3-1, after maintenance and replacement of the electronic device 7.

The container according to the invention is particularly well suited to use for storing a medical gas chosen from oxygen, a gas mixture N ₂ O/O ₂ , NO/N ₂ or He/O ₂ , or medical air , advantageously medical grade oxygen.

Claims (15)

Container (1) for fluid under pressure, in particular a gas cylinder, comprising a container body (1-1) having an internal volume (2) for keeping a fluid under pressure and equipped with a dispensing tap (3) of fluid comprising: - a valve body (3-1) comprising an internal fluid circuit (3-2) for conveying the pressurized fluid coming from the internal volume of the container body (1-1), - pressure measuring means (4) configured to measure at least the pressure of the fluid within said internal fluid circuit, said pressure measuring means (4) comprising a pressure sensor (4-1) connected to the pressure circuit internal gas (3-2) to carry out one or more pressure measurements and - an electronic device (7) comprising main data processing means (5) with at least one main microprocessor (5-1) configured to process the pressure measurement(s) carried out by the pressure measuring means (4), characterized in that : - the electronic device (7) comprises a rigid external housing (7-1), the main data processing means (5) being arranged in the housing (7-1) of the electronic device (7), - the pressure measuring means (4) comprise additional data processing means (42) comprising at least one additional microprocessor (4-7) for computer processing the measurements made by the pressure sensor (4-1) and obtaining measurements processed, and - the pressure measuring means (4) are arranged in the valve body (3-1) in a manner dissociated from the electronic device (7) by being only electrically connected to the electronic device (7) by electrical connection means (20 ) comprising a flexible electrical cable (20-1) comprising at least 4 electrical wires connecting the additional data processing means (42) of the pressure measuring means (4) to the main data processing means (5) of the device electronic (7) so as to provide them with processed measurements coming from the additional data processing means (42). Container according to claim 1, characterized in that the sheet (20-1) comprises 4 to 20 electrical wires arranged in parallel to each other. Container according to one of the preceding claims, characterized in that the pressure measuring means (4) comprise a combined pressure and temperature sensor (4-1) for carrying out pressure and temperature measurements of the fluid. Container according to claim 1, characterized in that the main data processing means (5) of the electronic device (7) comprise at least one main microprocessor arranged on a main electronic card. Container according to claim 1, characterized in that the electrical cable (20-1) is connected via a first end (20-1A) to the main data processing means (5) of the electronic device (7) and via a second end (20-1B) to the pressure measuring means (4), Container according to claim 5, characterized in that the electrical cable (20-1) is connected via the second end (20-1B) to a cable connector (4-7) of the sensor (4-1) of the means of pressure measurement (4), Container according to one of claims 1 to 6, characterized in that the pressure measuring means (4) are arranged in a sensor housing (21) arranged in the valve body (3-1). Container according to claim 7, characterized in that the sensor housing (21) communicates fluidly with the internal fluid circuit (3-2) of the valve body (3-1). Container according to claim 8, characterized in that the sensor housing (21) communicates fluidly with the internal fluid circuit (3-2) of the valve body (3-1) via a measuring port (22) arranged in a bottom (21-1) of the sensor housing (21). Container according to one of claims 1 to 3, characterized in that the main data processing means (5) of the electronic device (7) are configured to determine a residual gas pressure or a gas autonomy by processing the measurements of pressure or pressure and temperature, provided by the pressure measuring means (4). Container according to claim 1, characterized in that : - the at least one main microprocessor (5-1) is arranged on a main electronic card and/or - the at least one additional microprocessor (4-7) is arranged on an additional electronic card. Container according to claim 3, characterized in that the combined pressure and temperature sensor (4-1) is configured to measure temperatures between -40°C and +70°C and pressures between 0 and at least 150 bar abs. Container according to claim 2, characterized in that the sheet (20-1) comprises 4 to 15 electrical wires arranged in parallel to each other. Container according to claims 1 and 10, characterized in that the electronic device (7) comprises a digital display for displaying the residual gas pressure and/or the gas autonomy determined by the main data processing means (5) of the electronic device (7). Use of a container (1) according to one of the preceding claims, for storing or supplying a gas under pressure, in particular a medical gas, chosen from oxygen, air or a gas mixture N ₂ O/O ₂ , NO/N ₂ or He/O ₂ .

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