• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Pressurized fluid bottle tap comprising a draw-off circuit (3, 11), a storage and data-processing acquisition device (7) and at least one display (8), a pressure sensor (10) for measuring the pressure within the storage volume of a bottle (2) of fluid connected to the valve (1), wherein when the variation of the signal representative of the fluid pressure measured by the pressure sensor (10) is greater than at a determined withdrawal threshold, the storage acquisition and data processing device (7) is configured to detect a gas withdrawal and, in response, to control the display display (8) of at least information relating to said withdrawal.
    公开号:FR3016681A1
    申请号:FR1450528
    申请日:2014-01-22
    公开日:2015-07-24
    发明作者:Christophe Roland Rezel;Amelie Carron;Philippe Rudnianyn;Catherine Vivier;Beatriz Lopez
    申请人:Air Liquide SA;LAir Liquide SA pour lEtude et lExploitation des Procedes Georges Claude;
    IPC主号:
    专利说明:

    [0001] The present invention relates to a valve for a bottle of fluid under pressure and a corresponding bottle. The invention more particularly relates to a valve for a bottle of pressurized fluid comprising a body provided with an end intended to be mounted in the orifice of a bottle, the valve body housing at least one withdrawal circuit comprising a first end. upstream for communicating the storage volume of a bottle of pressurized fluid and a second downstream end intended to be connected to a user member of the withdrawn gas, said at least one circuit comprising an isolating member for opening or closing said withdrawal circuit, the valve comprising an electronic data indicating device (s) relative to the fluid content in a bottle connected to the tap, the electronic indication device comprising a storage acquisition member and of data processing and at least one data display connected to the data acquisition and data acquisition device, the robi net further comprising a pressure sensor for measuring the pressure within the storage volume of a fluid bottle connected to the valve, the pressure sensor being connected to the data acquisition and data acquisition member for transmit to the latter a signal representative of the measured fluid pressure.
    [0002] The invention relates to a valve provided with an electronic device for indicating physical data relating to the contents of a bottle of pressurized fluid, in particular gas under pressure. The invention relates in particular to a so-called electronic and digital pressure gauge device. For example, reference may be made to document FR2868160A1 which describes an example of such a device.
    [0003] Such a device comprises a pressure sensor and an electronic logic that calculates and displays fluid quantity and / or autonomy data. To calculate and display such reliable autonomy information the device must perform several successive pressure measurements before evaluating the flow rate selected by the tap user. This generates a calculation time that does not allow to display immediately a range or withdrawal rate selected. A time of thirty to sixty seconds may for example be necessary. In addition, this device also has an identical reaction time in case of change of the withdrawal parameters (change of the selected withdrawal rate ...). In addition, a bottle of pressurized fluid (gaseous oxygen in particular) can be used for different applications (supply of a fan or directly of a patient). In some cases known devices do not provide useful information to users. Such a device also does not allow to report certain risk situations or certain failures. An object of the present invention is to overcome all or part of the disadvantages of the prior art noted above. For this purpose, the valve according to the invention, moreover in accordance with the generic definition given in the preamble above, is essentially characterized in that when the variation of the signal representative of the fluid pressure measured by the sensor of pressure is greater than a determined withdrawal threshold, the storage acquisition and data processing member is configured to detect a gas withdrawal and, in response, to control the display on the display of at least one relative piece of information. audit racking. This makes it possible to quickly and automatically indicate to the user that gas is drawn off, either because of a supply to a medical fan, or because of a leak. Furthermore, embodiments of the invention may include one or more of the following characteristics: the variation of the signal representative of the fluid pressure measured by the pressure sensor is greater than said withdrawal threshold; acquisition of storage and data processing is configured to detect, from the signal of the pressure sensor, at least one characteristic of the pace of the variation of fluid pressure in the bottle due to the withdrawal, - said characteristic of the The shape of the variation of fluid pressure in the bottle comprises at least one of: a periodic character of the pressure variation or the quantity, the frequency of the variation of pressure or quantity, the organ of storage and data processing acquisition is configured to detect a draw corresponding to the fluid supply of a medical ventilator from said feature of the the appearance of the variation of fluid pressure in the bottle and for controlling the display on the display of at least one corresponding information relating to the supply of fluid to a medical ventilator, - the acquisition member for storage and data processing is configured to detect a withdrawal corresponding to the fluid supply of a medical ventilator from said characteristic of the rate of variation of fluid pressure in the bottle and to control the display on the display of at least one corresponding information relating to the supply of fluid to a medical ventilator, the valve comprises first and second withdrawal circuits, the first withdrawal circuit each comprising an upstream first end intended to communicate the storage volume of the medical device; a bottle of pressurized fluid and a second downstream end intended to be connected to a user organ of the gas withdrawn, the first extraction circuit comprising a regulating member of the flow rate and / or the pressure of the fluid withdrawn between its upstream and downstream ends, the valve comprising a manual control member of the regulating member, the control member being relatively movably mounted; the body of the valve and cooperating with the regulating member to control the flow rate and / or the fluid pressure admitted to flow from the upstream end to the downstream end according to the position of the control member relative to the body, the regulating member being displaceable between at least one opening position of the circuit and a so-called "closing" position corresponding to a closing of the first withdrawal circuit, in the closed position of the regulating member the flow of admitted fluid to pass from the upstream end to the downstream end being zero, that is to say that the isolation member of the first circuit comprises the regulating member, the valve comprising a sensor of position of the regulating member, connected to the storage acquisition and data processing member for transmitting thereto a signal representative of its open or closed position, the second withdrawal circuit comprising a portion avoiding the regulator of the flow rate and / or the pressure of the first withdrawal circuit and, when the regulating member is in its closed position and that the variation of the signal representative of the fluid pressure within a bottle is greater than the withdrawal threshold, the data acquisition and data acquisition member is configured to detect a fluid withdrawal via the second withdrawal circuit or via a fluid leak and to control the display on the display of the fluid. information relating to this withdrawal, the position sensor of the isolation member measures or detects the position of the manual control member of the regulating member, the position sensor being connected to to the storage acquisition and data processing member for transmitting thereto a signal representative of the flow rate and / or the fluid pressure imposed by the regulating member from the detected position of the control member; in response to the flow rate and / or imposed pressure signal measured by the position sensor and to the pressure signal measured by the pressure sensor, the storage and data processing member is configured to calculate and display on the display information on the use of the tap (withdrawal via the first or via the second draw-off circuit and possibly information relating to a possible leak, - when the regulating member is in its position of closing and that the variation of the signal representative of the fluid pressure measured by the pressure sensor is lower than the withdrawal threshold, the storage acquisition and processing member is configured to control the display on the display of a fixed information relating to the pressure and / or the quantity of fluid in the bottle, the withdrawal threshold corresponds to a value of between 5 and 15 mbar / minute and preferably equal to 10mbar / minute (0.051 / min), - when the regulating member is in its closed position and the variation of the signal representative of the fluid pressure is greater than the withdrawal threshold, the organ of storage and data processing acquisition is configured to calculate a remaining fluid autonomy information from the measurement of the initial pressure signal and the variation, from this pressure signal given by the pressure sensor, and in that the data acquisition and data acquisition device is configured to control the display on the display of this calculated autonomy information and / or information relating to the pressure or quantity i nitiale fluid in the bottle. all or part of the detected and / or calculated information is displayed on the display and / or transmitted by electric signal with or without wire and / or signaled by audible means, at least one of the components and in particular one of the sensors (of position, of pressure) is of the electric type and powered by a battery and / or an inductive system, said at least one component being able to be fed non-continuously to save energy, the acquisition member of Storage and data processing can be configured to provide this power supply at the time of a measurement.
    [0004] The invention also relates to a bottle comprising a valve according to any one of the above characteristics or below. The invention may also relate to any alternative device or method comprising any combination of the above or below features. Other features and advantages will appear on reading the description below, with reference to the figures in which: - Figure 1 shows a side view, schematic and partial, illustrating a valve mounted on a pressurized gas cylinder according to an exemplary possible embodiment of the invention, - Figure 2 schematically and partially illustrates the structure and operation of a portion of the valve of Figure 1 - Figures 3 to 5 schematically illustrate and The structure and operation of respectively three examples of position sensors of a valve according to the invention are shown in FIG. 6. FIG. 6 schematically represents two curves illustrating examples of signals generated by one or more position sensors of FIG. FIGS. 7 and 8 schematically and partially illustrate the structure and operation of respectively a fourth example and a fifth example of Tap position sensor according to the invention; FIG. 9 schematically shows an example of a pressure curve measured as a function of time. Figure 1 shows schematically a bottle 2 of pressurized gas provided with a valve 1 capable of implementing the invention.
    [0005] The valve 1 comprising a body provided with an end intended to be mounted in the orifice of a bottle 2 of fluid under pressure (for example by screwing). Typically the valve body housing at least one withdrawal circuit 11 comprising an upstream first end intended to communicate the storage volume of a bottle of pressurized fluid and a second downstream end intended to be connected to a user organ of the withdrawn gas, for example via an outlet valve valve 101 self-sealing that is to say integrating a closure valve which is opened by a withdrawal socket connected thereto (eg via a notched socket). This valve integrated in the outlet connection 101 thus forms an isolation member for opening or closing said circuit 11 for withdrawal. Of course, in place of or in addition to this valve, a separate isolation valve may be provided on the circuit 11. Similarly, and as shown in Figure 1, a flow regulator or a pressure reducer 14 may be provided in this circuit 11. This circuit 11 for withdrawal is for example provided to provide a gas at a controlled pressure (via a pressure regulator 14). For example, the second withdrawal circuit 11 provides an adjustable or fixed pressure and of the order of 3 to 10 bar to a user device.
    [0006] The valve also comprises an electronic device 6 indicating data (s) relative to the fluid content in a bottle connected to the valve 1. The electronic indication device 6 preferably comprises a storage acquisition member 7 and data processing and at least one data display 8 connected to the storage acquisition and data processing member 7. The storage acquisition and data processing unit 7 comprises for example a computer and / or a microprocessor or any other equivalent system. Of course, this device may comprise one or more data receiving members (by wired and / or wireless connection) as well as one or more data transmission members (by wired and / or wireless connection). The valve further comprises a pressure sensor 10 for measuring the pressure within the storage volume of a bottle 2 of fluid connected to the valve 1 (see Figure 2).
    [0007] The pressure sensor 10 is connected to the storage acquisition and data processing member 7 for transmitting thereto (wired and / or wireless) a signal representative of the measured fluid pressure, especially in time. real or periodically.
    [0008] According to an advantageous characteristic, when the variation of the signal representative of the fluid pressure measured by the pressure sensor 10 is greater than a determined withdrawal threshold, the storage acquisition and data processing member 7 is configured to detect a gas withdrawal and, in response, to control the display on the display 8 of at least one information relating to said withdrawal. That is, the storage acquisition and data processing member 7 makes it possible to detect a withdrawal and inform the user in a relevant manner. Preferably, when the variation of the signal representative of the fluid pressure measured by the pressure sensor 10 is greater than said withdrawal threshold, the storage acquisition and data processing member 7 is configured to detect, from the signal of the pressure sensor 10, at least one characteristic of the shape of the variation of fluid pressure in the bottle due to the withdrawal. The at least one characteristic of the shape of the variation of fluid pressure in the bottle comprises for example at least one of: a periodic character of the pressure variation or the quantity, the frequency of the variation of pressure or of quantity (see Figure 9 which illustrates an example of pressure variation P as a function of time). That is, the storage acquisition and data processing member 7 may be configured to detect a draw corresponding to the fluid supply of a medical ventilator from said feature of the pace. the variation of fluid pressure in the bottle and for controlling the display on the display 8 of at least one corresponding information relating to the supply of fluid to a medical ventilator. This provides useful information to a user including indicating that the bottle feeds a medical fan. The storage acquisition and data processing member 7 can provide relevant information relating to this use.
    [0009] As illustrated in FIG. 1, the valve body 1 can house another withdrawal circuit 3 (at least partially distinct from the previous circuit 11) comprising a first upstream end 13 communicating with the storage volume of the bottle 2. This circuit 3 extraction can comprise a second downstream end 23 intended to be connected to a user member of the withdrawn gas (for example a patient in the case of oxygen or another medical gas). This draw-off circuit 3 preferably comprises a device 4 for regulating the flow rate and / or the pressure of the fluid drawn between the upstream and downstream ends 13. This regulating member 4 is, for example, a calibrated orifice flow regulator 16 enabling to select a gas flow withdrawn (see the diagram of Figure 3). Of course any other regulator may be considered. The valve 1 comprises a member 5 for manual control of the regulating member 4. The control member 5 is mounted movably relative to the body of the valve 1 and cooperates with the regulating member 4 to control the flow rate and / or the fluid pressure admitted to circulate according to the position of the control member relative to to the body of the faucet. The control member 5 comprises for example a rotary wheel. Of course, any other suitable system can be envisaged (pivoting lever, digital control, wireless control via a remote control, etc.).
    [0010] For example, the control member selects a calibrated orifice and / or controls a rate restriction valve based on its position among a plurality of stable discrete positions or a plurality of positions of a continuous displacement. . The valve 1 may advantageously comprise a sensor 9 of the position of the manual control member 5 of the regulating member 4. The position sensor 9 is connected to the storage acquisition and data processing member 7 to transmit to the latter a signal representative of the flow rate and / or the fluid pressure imposed by the regulating member 4. For example, the position sensor 9 of the control member 5 comprises a converter of the mechanical displacement of the control member into an electrical signal that can be used by the storage acquisition and data processing member 7. The detector is for example integral with a fixed part of the valve, or respectively of the control member, the detector 69, 79 providing an electrical or digital signal determined according to the position of the control member. This signal can be provided wired and / or wireless. The position sensor 9 of the control member 5 may comprise, for example, at least one of: a capacitive sensor, a magnetic sensor, a mechanical sensor. The storage acquisition and data processing member 7 can be configured, in response to the reception of the pressure signal delivered by the sensor 10, in order to calculate and display on the display 8 autonomy or content information. fluid remaining. Preferably the member 5 for manual control of the regulating member 4 is movable in a so-called "closing" position corresponding to a closure of the withdrawal circuit 3 concerned. That is to say that the fluid flow admitted to pass from the upstream end 13 to the downstream end 23 is zero. In the case where the manual control member 5 is in its closed position and the variation of the signal representative of the fluid pressure within a bottle 2 is less than a determined threshold of variation (for example equivalent to a pressure drop of 10 mbar / min (0.051 / min) measured by the pressure sensor 10, the storage acquisition and data processing member 7 is preferably configured to control the display on the display 8 20 of fixed information relating to the pressure and / or the amount of fluid in the bottle 2. That is to say that the device detects that the bottle 12 is not withdrawn and displays for example information relating to In the case where the regulating member 4 is not common to the two withdrawal circuits 3 1, 11, withdrawal via one of the circuits 11 is therefore possible even if this regulating member 4 is in position. The racking circuit 11 may for example withdrawing gas from the cylinder 2 independently of the withdrawal circuit 3 provided with the regulating member 4. Thus, when the manual control member 5 is in its closed position and the variation of the signal representative of the fluid pressure within a cylinder 2 (measured by the pressure sensor 10) is greater than a threshold of determined variation (for example 25mbar per minute), the storage acquisition and data processing member 7 can detect a withdrawal of fluid via the second circuit 11 of withdrawal or, if this second circuit 11 of withdrawal is not used, report any leakage of fluid. The storage acquisition and data processing member 7 can, if necessary, control the display on the display 8 or the sending (wirelessly, wired or audibly) of information relating to a withdrawal via the circuit 11 of withdrawal concerned and or relating to a leak (warning signal). In particular, when the manual control member 5 is in its so-called closing position and the variation of the signal representative of the fluid pressure within a bottle is greater than a determined variation threshold (for example 25 mbar per minute). minute), the storage acquisition and data processing member 7 can be configured to detect at least one characteristic of the shape of the variation of fluid pressure in the bottle due to the withdrawal via the withdrawal circuit 11 concerned (as previously described).
    [0011] As illustrated schematically in FIG. 9, this makes it possible to detect, after two to three pressure oscillations, for example a periodic withdrawal corresponding to a supply of gas to a respiratory ventilator. Indeed, even if the gas withdrawn does not pass through the flow regulator 4, the flow rate is regulated directly by a ventilator and depends on the breathing of the patient. This flow thus delivered is not constant but oscillates in time (according to the breathing of the patient). The storage acquisition and data processing unit 7 may be configured to detect (recognize) a characteristic pressure drop of a ventilation according to the following principle: - measurement of the pressure signal in a close periodic manner (for example all 0.1 to two seconds, especially every second), - identification of a niche type signal having a frequency of five to twenty-five slots (breaths) per minute). To calculate the remaining gas autonomy from such a signal, the storage acquisition and data processing member 7 can be configured to measure the pressure drop on the optimums to deduce the equivalent decay slope. (see reference 15 in FIG. Alternatively or cumulatively, the storage acquisition and data processing unit 7 can be configured to average the pressure drop over a relatively long time (several minutes, for example ten minutes) so as to erase the inaccuracies of the data. picture. In the case where this pressure signal does not correspond to a ventilation signal (for example a continuous decreasing variation), the storage acquisition and data processing member 7 can determine that it is a leakage or improper use of the gas and may report it in the same way. Thus, in this case, the simultaneous detection of the closed position (graduation "0" = "zero" for example) on the position detector 5 and a pressure drop, it is thus possible to detect instantly and automatically the use of the bottle 2. An autonomy calculation algorithm adapted to this method of withdrawal can be achieved by the organ 7 acquisition of storage and data processing.
    [0012] This autonomy calculation algorithm based on the pressure measurement 10 can thus be automatically activated. In addition, when the manual control member 5 is in its closed position and the variation of the signal representative of the fluid pressure within a bottle 2 is greater than a determined threshold of variation, the body 7 of FIG. Storage and data acquisition acquisition may be configured to calculate fluid remaining information from the measurement of the initial pressure signal and the variation of this pressure signal given by the pressure sensor. The storage acquisition and data processing member 7 can in particular be configured to control the display on the display 8 of this calculated autonomy information and / or information relating to the pressure or the initial quantity of fluid. in the bottle 2. The pressure sensor 10 can be located for example at the upstream end of the first withdrawal circuit 3 and / or at the second 11 withdrawal circuit.
    [0013] In addition, the storage acquisition and data processing member 7 may be configured, in response to the reception of this flow rate and / or imposed pressure signal, to control the display on the display 8 of FIG. relative information of the flow rate and / or the fluid pressure imposed by the regulating member 4.
    [0014] As illustrated in FIG. 3, the position sensor 9 of the control member 5 may comprise, for example, a mechanism 19 meshing with the control member 5 (a gearing and / or notching system) and a potentiometer 39. mechanism comprises a movable part 29 (for example a wheel or a rod or a rack) forming a slider of the potentiometer 39. In this way, the position sensor 9 provides a value of tension and / or resistance determined according to the position of the control member 5. In the example of FIG. 4, the position sensor 9 of the control member 5 comprises a mechanism meshing with the control member 10 comprising an optical and / or digital coder 49, for example a wire coder ( conductive wire and a ground wire). The encoder 49 provides a digital signal determined according to the position of the control member. Depending on the position of the mechanism, one or more wires are energized or short-circuited forming a plurality of distinct signals to characterize different positions (e.g. 2114 for a n-wire system). As illustrated in FIG. 5, the position sensor 9 of the control member 5 can comprise a magnetic system comprising at least one magnet 59 integral with the control member 5 and at least one magnetic field detector 69, 79 of the at least one magnet 59. For example three magnets 59 20 are integral with the control member 5. In case of displacement (such as a rotation) of the control member 5, a detector 69 detects for example a magnetic field E as a function of the displacement D which oscillates and makes it possible to characterize a plurality of positions. When the device comprises a second detector 79 (or more), several separate signals can be operated simultaneously to improve the detection of distinct positions. As illustrated in FIGS. 7 and 8, the position sensor 9 of the control member 5 may comprise a capacitive system measuring an electrical capacitance between a magnetic fixed reference 89 and a mobile part 99 connected to the control member 30. All these systems have the advantage of reliable detection without the need to provide electrical son associated with a moving part of the mechanism.
    [0015] The potentiometer system and more generally each detection system can be easily calibrated during manufacture. For example, the potentiometer 39 or sensor 9 of the position sensor 9 of the control member 5 can be calibrated by measuring the value of voltage or resistance (see magnetic field and capacitance) that it provides corresponding to the position called closing (zero flow). Then, it is possible to measure the value of voltage or resistance provided by the potentiometer 39 corresponding to a position of the extreme control member 5 with respect to the closed position (for example 15 liters / minute). The intermediate values of voltage or resistance provided by the potentiometer 39 are respectively assigned to the intermediate positions of the control member 5 between the closed position and the extreme position. (Idem for the detection of another physical quantity, magnetic field, capacity ... where the intermediate positions of the signal can be assigned respectively to the intermediate positions of the control member). Alternatively or cumulatively, the potentiometer 39 of the position sensor 9 of the control member 5 can be calibrated by measuring the voltage or resistance value that it provides corresponding to a position of the control member 5 in which no variation of The pressure is measured by the pressure sensor for a predetermined time, for example one to three minutes. This position (this signal value) is defined as the closing position of the circuit (zero flow). This mode of definition of the closed position can be applied to the other examples (magnetic field, capacity ...).
    [0016] The storage acquisition and data processing member 7 can thus be configured to receive both the pressure signal P measured from the pressure sensor 10 and the flow and / or pressure signal D supplied by the sensor 9. position. The storage acquisition and data processing member 7 can thus be programmed to calculate a fluid autonomy information remaining from these two pieces of information, the remaining fluid autonomy being determined for example by calculating, from of the initial pressure measured, the theoretical time reduction of pressure or the amount of gas generated by the flow and / or the pressure D of withdrawal imposed by the regulating member 4.
    [0017] In addition, the storage acquisition and data processing member 7 can be configured to: calculate the variation of quantity or pressure of the real fluid measured by the pressure sensor, calculate the variation of quantity or of theoretical fluid pressure imposed by the regulating member 4, - comparing the change in quantity or actual pressure measured by the pressure sensor 10 with the variation in quantity or theoretical pressure imposed by the regulating member 4 and - generating a warning signal in case of divergence between them above a determined safety threshold (for example a divergence of 15 to 30% and in particular 25%) The information of autonomy or fluid content remaining in the bottle 2 can be expressed in time remaining (respectively in remaining quantity) by dividing the initial pressure measured by the pressure sensor 10 (or respectively, a quantity of the current gas), by the variati the theoretical pressure imposed by the regulating member 4 (respectively the quantity variation imposed by the regulating member (4)), according to a formula for example of the type: Time remaining = initial pressure / pressure variation imposed (or respectively: Remaining time = Remaining fluid content / imposed quantity variation). The variations of quantity or theoretical pressure can be calculated for example via the equation of the perfect gas PV = nRT or real PV = ZnRT (SI units), with P the measured pressure, V the known volume of the bottle, n the quantity , R is the ideal gas constant and T is the measured or approximated temperature at the measured ambient temperature, Z is the known compressibility factor (table or calculation). Similarly conversions between pressure and quantity can be calculated via the perfect gas equation or any other equivalent formula, the volume of the bottle 2 being known and indicated in the organ 7 acquisition of storage and data processing and the temperature can be measured by a sensor in the bottle or outside ambient or calculated or filled or approximated The storage acquisition and data processing member 7 can be configured to calculate information autonomy or fluid content over a specified time interval of between fifteen seconds and ten minutes, and preferably between thirty seconds and five minutes, from the pressure signal measured by the pressure sensor. The storage acquisition and data processing unit 7 can also be configured to compare this autonomy information calculated on the basis of the pressure signal P measured with respect to the theoretical autonomy information calculated from the variation of quantity or pressure imposed by the regulating member 4.
    [0018] The dynamic pressure measurement can make it possible to readjust, if necessary more precisely, the display of the actual flow withdrawn and / or the displayed autonomy. Similarly, the storage acquisition and data processing unit 7 can be configured to automatically recalculate and possibly display an update of the autonomy or fluid content information on receipt of a signal from the position sensor 9 indicating a flow rate change and / or the fluid pressure imposed by the control member 4 via the control member 5. The manual control member 5 and / or the regulating member 4 can be movable according to a plurality of discrete positions (mechanically stable or not) respectively corresponding to flow values and / or the fluid pressure allowed to pass from the end 13 upstream to the downstream end. According to a possible advantageous feature, when the manual control member 5 is disposed in an intermediate position between two respective adjacent flow rate values and / or the fluid pressure admitted to pass from the upstream end 13 to the downstream end 23, the storage acquisition and data processing member 7 is configured to select and display on the display 8 one or both of these adjacent values, and preferably at the most critical or unfavorable value for the user. Alternatively, in this situation, the storage acquisition and data processing unit 7 can be configured to display on the display 8 a range of values delimited by these adjacent values or to delete all or part of the display of these values. values.
    [0019] This makes it possible to ergonomically alert the user of a wrong manipulation by displaying relevant but penalizing information forcing him to correct his selection (or by removing this display). For example, when the manual control member is disposed in an intermediate position between two respective adjacent flow rate values, the data acquisition and data acquisition member 7 is configured to calculate and display on the display 8 an autonomy or fluid content information remaining in the bottle based on the highest value of the two adjacent values.
    [0020] Thus, if for example the user positions the control member between the positions n liter per minute and n + 1 liter per minute (where n is an integer), the storage acquisition and data processing unit 7 can be configured to calculate a range based on the flow rate value taken from n + 1 liter per minute (less autonomy than it had been calculated with the value of n liter per minute). Likewise, when the manual control member 5 is disposed in an intermediate position between two respective adjacent flow rate values, the storage and data processing acquisition member 7 can be configured to display on the display 8 d information relating to the withdrawn flow rate imposed by the regulating member 4 corresponding to the lowest value of the two adjacent values. Thus, if for example the user positions the control member between the positions n liter per minute and n + 1 liter per minute (where n is an integer), the storage acquisition and data processing unit 7 can be configured to display on the display 8 information based on the flow rate value taken from n liter per minute (the lowest rate that may for example be below the medical prescription). This will prompt the user to correct the flow selection. The device may be configured in this case to deliver a flow of fluid corresponding to one of the two adjacent values, in particular the displayed value.
    [0021] In addition, the storage acquisition and data processing member 7 may be configured to include a guaranteed seal function indicating that the bottle 2 has not been used following a filling. Thus, before a first racking, the storage acquisition and data processing unit 7 can control the display on the display 8 of a fixed information relating to the fluid content in the bottle 2 (and / or information of the "full bottle" type) as long as the position sensor 9 has not transmitted a signal representative of a flow rate and / or the fluid pressure withdrawn from the tank 2 during a determined period of time and / or corresponding to a quantity determined fluid (for example 20 liters of gas withdrawn). This detection can be ensured or supplemented by the information given by the pressure sensor. Although the invention is relatively simple and inexpensive it is easy to see that it allows faster display of flow rate and autonomy information. The invention is advantageously applied to pressurized gas cylinders, in particular bottles containing oxygen under pressure.
    权利要求:
    Claims (11)
    [0001]
    REVENDICATIONS1. A valve for a pressurized fluid bottle comprising a body provided with an end intended to be mounted in the orifice of a bottle, the valve body (1) housing at least one withdrawal circuit (3, 11) comprising a first upstream end (13) for communicating the storage volume of a bottle of pressurized fluid and a second downstream end (23) intended to be connected to a user body of the withdrawn gas, said at least one circuit (3, 11) comprising an isolating member for opening or closing said withdrawal circuit (3, 11), the valve (1) comprising an electronic data indicating device (6) relative to the contents of fluid in a bottle connected to the tap (1), the electronic indication device (6) comprising a data storage and data acquisition member (7) and at least one data display (8) connected to the organ (7) for acquisition of storage and treatment of e, the valve further comprising a pressure sensor (10) for measuring the pressure within the storage volume of a bottle (2) of fluid connected to the valve (1), the pressure sensor (10) being connected to the storage acquisition and data processing element (7) for transmitting thereto a signal representative of the measured fluid pressure, characterized in that when the variation of the signal representative of the fluid pressure measured by the pressure sensor (10) is greater than a determined withdrawal threshold, the storage acquisition and data processing member (7) is configured to detect a gas withdrawal and, in response, to control the display on display (8) at least one information relating to said withdrawal.
    [0002]
    2. Tap according to claim 1 characterized in that when the variation of the signal representative of the fluid pressure measured by the pressure sensor (10) is greater than said bleed threshold, the body (7) acquisition of storage and data processing is configured to detect, from the signal of the pressure sensor (10), at least one characteristic of the pace of the variation of fluid pressure in the bottle due to the withdrawal.
    [0003]
    3. Tap according to claim 2 characterized in that said characteristic of the shape of the fluid pressure variation in the bottle comprises at least one of: a periodic character of the pressure variation or quantity, the frequency the variation of pressure or quantity.
    [0004]
    4. Tap according to claim 3 characterized in that the member (7) for acquisition of storage and data processing is configured to detect a withdrawal corresponding to the fluid supply of a medical fan from said characteristic the appearance of the variation of fluid pressure in the bottle and to control the display on the display (8) of at least one corresponding information relating to the fluid supply of a medical fan.
    [0005]
    5. Tap according to any one of claims 1 to 4 characterized in that it comprises a first (3) and a second (11) withdrawal circuits, the first circuit (3) for withdrawal each comprising an upstream first end intended communicating the storage volume of a bottle of pressurized fluid and a second downstream end intended to be connected to a user body of the gas withdrawn, the first withdrawal circuit (3) comprising a flow control member (4) and or the pressure of the fluid withdrawn between its upstream (13) and downstream (23) ends, the valve (1) comprising a member (5) for manual control of the regulating member (4), the member (5) ) being movably mounted relative to the body of the valve (1) and cooperating with the regulating member (4) to control the flow rate and / or the fluid pressure allowed to flow from the upstream end (13) to the downstream end (23) according to the position of the control member (5) relative to the body (5), the regulating member (4) being displaceable between at least one opening position of the circuit (3) and a so-called "closing" position corresponding to a closing of the first circuit (3) of withdrawal, in the closed position of the regulating member (4), the flow rate of the fluid admitted to pass from the upstream end (13) to the downstream end (23) being zero, that is to say that isolating member of the first circuit (3) comprises the regulating member (4), the valve (1) comprising a sensor (9) for the position of the regulating member (4) connected to the member ( 7) acquisition destocking and data processing to transmit to the latter a signal representative of its open or closed position, the second circuit (11) for withdrawal comprising a portion avoiding the control member (4) of the flow rate and / or the pressure of the first withdrawal circuit (3), and in that, when the regulating member (4) is in its closed position ture and that the variation of the signal representative of the fluid pressure within a bottle is greater than the withdrawal threshold, the member (7) for acquisition of storage and data processing is configured to detect a withdrawal of fluid via the second withdrawal circuit (11) or via a leakage of fluid and control the display on the display (8) of information relating to this withdrawal.
    [0006]
    6. Tap according to claim 5, characterized in that the sensor (9) of the position of the insulating member (4) measures or detects the position of the member (5) for manual control of the body (4). ), the position sensor (9) being connected to the storage acquisition and data processing member (7) for transmitting to the latter a signal representative of the flow rate and / or the fluid pressure imposed by the control member (4) from the detected position of the control member (5).
    [0007]
    Valve according to claim 5 or 6, characterized in that in response to the flow rate and / or imposed pressure signal measured by the position sensor (5) and to the pressure signal measured by the pressure sensor (10), the storage and data processing acquisition device (7) is configured to calculate and display on the display (8) information relating to the mode of use of the tap (withdrawal via the first (3) or via the second circuit (11) of withdrawal) and possibly information relating to a possible leak.
    [0008]
    8. Valve according to any one of claims 5 to 7, characterized in that when the regulating member (4) is in its closed position and the variation of the signal representative of the fluid pressure measured by the sensor ( 10) is less than the withdrawal threshold, the storage acquisition and data processing member (7) is configured to control the display on the display (8) of a fixed information relating to the pressure. and / or the amount of fluid in the bottle (2).
    [0009]
    9. Tap according to claim 8, characterized in that the withdrawal threshold corresponds to a value between 5 and 15 mbar / minute and preferably equal to 10mbar / minute (0.051 / min).
    [0010]
    10. Valve according to claim 9, characterized in that, when the control member (4) is in its closed position and the variation of the signal representative of the fluid pressure is greater than the withdrawal threshold, the organ (7) storage acquisition and data processing is configured to calculate a remaining fluid autonomy information from the measurement of the initial pressure signal (P) and the variation, from this pressure signal (P) given by the pressure sensor (10), and in that the storage acquisition and data processing member (7) is configured to control the display on the display (8) of this information. of calculated autonomy and / or information relating to the pressure or the initial quantity of fluid in the bottle (2).
    [0011]
    11. Bottle of pressurized fluid, particularly pressurized gas, comprising a valve according to any one of claims 1 to 10.
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    同族专利:
    公开号 | 公开日
    CN106133432B|2019-02-22|
    ES2690444T3|2018-11-21|
    CN106133432A|2016-11-16|
    AU2015208009B2|2019-02-14|
    WO2015110733A1|2015-07-30|
    AU2015208009A1|2016-08-25|
    US20170002983A1|2017-01-05|
    EP3097344A1|2016-11-30|
    FR3016681B1|2016-07-22|
    CA2937690A1|2015-07-30|
    AU2015208009C1|2019-06-20|
    PT3097344T|2018-11-07|
    EP3097344B1|2018-08-29|
    DK3097344T3|2018-10-29|
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    WO2012164240A2|2011-06-02|2012-12-06|Linde Aktiengesellschaft|A flow apparatus and monitoring system relating thereto|FR3058202A1|2016-11-03|2018-05-04|L'air Liquide, Societe Anonyme Pour L'etude Et L'exploitation Des Procedes Georges Claude|TAP FOR FLUID TANK AND BOTTLE COMPRISING SUCH FAUCET|
    FR3075310A1|2017-12-19|2019-06-21|L'air Liquide, Societe Anonyme Pour L'etude Et L'exploitation Des Procedes Georges Claude|PRESSURE FLUID VALVE AND BOTTLE|FR2868160B1|2004-03-24|2007-09-28|Taema Sa|SYSTEM FOR PROCESSING PRESSURE DATA IN A RESERVOIR|
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    TWM601306U|2019-03-29|2020-09-11|兆捷科技國際股份有限公司|Anti-leakage fluid carrier system and pressure regulating fluid distributor structure with pressure sensor and pressure regulating fluid distributor structure thereof|
    法律状态:
    2016-01-21| PLFP| Fee payment|Year of fee payment: 3 |
    2017-01-20| PLFP| Fee payment|Year of fee payment: 4 |
    2018-01-19| PLFP| Fee payment|Year of fee payment: 5 |
    2019-01-23| PLFP| Fee payment|Year of fee payment: 6 |
    2020-10-16| ST| Notification of lapse|Effective date: 20200905 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1450528A|FR3016681B1|2014-01-22|2014-01-22|VALVE FOR PRESSURIZED FLUID BOTTLE AND CORRESPONDING BOTTLE|FR1450528A| FR3016681B1|2014-01-22|2014-01-22|VALVE FOR PRESSURIZED FLUID BOTTLE AND CORRESPONDING BOTTLE|
    US15/113,100| US20170002983A1|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
    PCT/FR2015/050011| WO2015110733A1|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
    ES15702520.6T| ES2690444T3|2014-01-22|2015-01-06|Tap for a bottle of a pressurized fluid and corresponding bottle|
    DK15702520.6T| DK3097344T3|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and associated cylinder|
    AU2015208009A| AU2015208009C1|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
    PT15702520T| PT3097344T|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
    CN201580013010.1A| CN106133432B|2014-01-22|2015-01-06|Valve and corresponding bottle for pressurized fluid bottle|
    EP15702520.6A| EP3097344B1|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
    CA2937690A| CA2937690A1|2014-01-22|2015-01-06|Valve for a pressurized fluid cylinder and corresponding cylinder|
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