• 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:
    The invention relates to a flowmeter comprising a tubular body (21) having two axial ends, a flow measuring device carried by the tubular body, an electrical connection (46) extending outside the tubular body. The flow measuring device is associated with the tubular body (21) so as to allow the measurement of a flow of fluid flowing outside the tubular body (21), and said electrical connection (46) passes through the body tubular by at least one fluid-tight passage. The invention extends to a valve such as a fire hydrant incorporating at least one such flowmeter.
    公开号:FR3035498A1
    申请号:FR1553673
    申请日:2015-04-23
    公开日:2016-10-28
    发明作者:Mathieu Poque;Alain Ramond
    申请人:Yzatec SAS;
    IPC主号:
    专利说明:

    [0001] The invention relates to a flowmeter more particularly adapted to be incorporated in a valve or a fire hydrant. It also extends to such a valve. A flow meter is a device for measuring the flow velocity of a fluid that is to say a liquid or a gas, or a gaseous liquid mixture. Flowmeters having flow measurement devices requiring an electrical connection are particularly known. These include transducer flowmeters, particularly ultrasonic transducers, for measuring the flow velocity of a fluid using the duration of propagation of ultrasonic waves in the fluid. However, these flowmeters require the establishment of an electrical connection between the flowmeter and the environment outside the flow of the fluid with which the flowmeter is in contact, which, in certain configurations and / or applications, may pose problems. particular problems. The problem also arises of incorporating a flow meter inside a valve such as a fire hydrant. In addition, ultrasound transducer flowmeters may exhibit degraded performance when placed in an extreme environment such as the interior of a valve or pipe in which a fluid flows turbulently. The forces due to the flow of fluid then acting on the transducers can deform and / or weaken the transducers, and thus distort their measurements and / or reduce their life. However, the maintenance and / or replacement operations of such devices are often particularly complex and costly, especially when the device is installed on a difficult to access conduit, for example underground or submerged, and require the interruption of the device. flow and the corresponding installation. A valve is a device that regulates the flow of a fluid. A valve thus makes it possible to stop and modify the flow rate of a fluid. For example, a fire hydrant (or fire hydrant) is a valve whose main use is to supply water, emergency firefighters to fight against a fire. Measuring the flow rate of the water flow delivered by a hydrant is useful to ensure the proper functioning of this fire hydrant. It may also be useful to constantly monitor the flow rate of the water flow in the fire hydrant to send an alarm signal if abnormal use is found. An abnormal use of a fire hydrant can be observed during a water theft or after a fire hydrant has been damaged and there is a water leak.
    [0002] Several types of flowmeters for measuring a speed of a flow of water delivered by a fire hydrant are already known. Some of these flow meters are placed at the outlet (intake) of the fire hydrant. These known flowmeters are used for spot checks to verify the proper functioning of the fire hydrant. This provision involves several disadvantages. Indeed, for each control, the flowmeter must be assembled and dismounted thus causing a considerable loss of time. In addition, if such a flowmeter remains assembled outside a fire hydrant, it then presents a risk of degradation (accident, vandalism). CN203412037 discloses an automatic buried burglar alarm device comprising a flowmeter disposed on the underground pipeline assembled at the fire hydrant, a control unit and a communication system. Maintenance of the flowmeter of such a device is not easy because the ground must be dug to access the flowmeter. The invention therefore aims to overcome all of these disadvantages. It therefore aims generally to propose a flowmeter that can be installed simply and incorporated in a valve such as a fire hydrant, or a pipe such as a water pipe. The invention aims in particular to provide such a flowmeter 30 can be installed simply, and in particular within a valve such as a fire hydrant or a pipe such as a water pipe, while being able to be changed or repaired easily. The invention aims more particularly at providing such a device which is robust and compatible with an aggressive external environment, in particular which can be buried or immersed. The invention aims in particular to provide such a flowmeter which delivers reliable and accurate measurement signals regardless of the nature of the flow of the fluid and the possible variations thereof (which can possibly be abrupt and large amplitudes), and whose life is improved. The invention aims more particularly to provide such a device that is completely autonomous in its operation, preset to manufacture, and whose settings and / or characteristics are not likely to vary in operation, including because of its use in highly disturbed environments (high-speed and / or turbulent flows ...). The invention also aims to provide such a device that is simple, inexpensive in manufacturing, and has a small number of parts. The invention aims more particularly at providing such a flowmeter comprising a device for measuring the flow velocity of a fluid comprising at least one ultrasonic transducer. The invention also aims to propose a valve - particularly in particular but not exclusively a fire hydrant - incorporating at least one flowmeter. It is more particularly intended to provide such a valve 25 incorporating at least one flow meter having the advantages mentioned above. To do this, the invention relates to a flowmeter comprising: a tubular body having two axial ends, a flow measurement device carried by the tubular body, an electrical connection extending outside the tubular body, characterized in that: - the flow measurement device is associated with the tubular body so as to allow the measurement of a flow of fluid flowing outside the tubular body, - said electrical connection through the tubular body by at least one fluid-tight passage. In particular, advantageously and according to the invention, the tubular body is fluid-tight and encloses at least one electronic circuit of the flow measurement device. Thus, the tightness of the tubular body allows to immerse completely in the fluid.
    [0003] In addition, advantageously and according to the invention, at least one, in particular only one, of the axial ends of said tubular body comprises a fluid-tight passage for the electrical connection. This watertight crossing makes it possible to transmit the signals emitted by a transducer of the flowmeter to the outside without the electrical connection being in contact with the fluid, in particular with a humid medium.
    [0004] Furthermore, advantageously and according to the invention, said flow measuring device comprises at least one ultrasonic transducer - in particular at least two ultrasonic transducers vis-à-vis - comprising a proximal end assembled to said tubular body and extending to outside said tubular body to a distal end of said transducer. Thus, the flow velocity measurements of a fluid outside the tubular body can be performed simply, reliably, and accurately by ultrasound. An ultrasonic transducer comprises a rigid shell enclosing different components ensuring the operation of the transducer. The distal end of the transducer is therefore the distal end of the rigid shell of the transducer. Similarly, the proximal end of the transducer is the proximal end of the rigid shell of the transducer. In some embodiments and according to the invention, said tubular body is a straight tubular body extending along an axis passing through both axial ends. In these embodiments, advantageously and according to the invention, each ultrasonic transducer is orthogonal to the axis of said tubular body.
    [0005] Furthermore, preferably, the flowmeter comprises an assembly stirrup of the distal end of each transducer to said tubular body. The inventors have found that the simple fact of assembling the distal end of a transducer to the body by an assembly bracket improves the rigidity of the flow measurement device. In addition, it can provide a hyperstatic type assembly when the transducer is otherwise embedded in the body by its proximal end. Such an assembly of hyperstatic type makes it possible in particular, on the one hand, to considerably reduce the errors in the measurement signal, and on the other hand, to improve the mechanical connection between the transducer and the body, and in doing so, 10 to increase the life of the device. In particular, such a hyperstatic assembly makes it possible to limit the vibrations of each transducer under the effect of transient phenomena such as the establishment or interruption of the flow of the fluid or any turbulence in the flow of the fluid. In addition, the device can be precisely tuned to manufacture, and these settings are not disturbed in operation. The purpose of the assembly between the distal end of a transducer and the body is to prevent the relative displacements of this distal end relative to the body (and therefore with respect to its proximal end) in at least one direction orthogonal to the longitudinal direction of the transducer, i.e. to prevent bending deformations of the transducer corresponding to a displacement of the distal end at least in said orthogonal direction. A flowmeter according to the invention is intended to be placed in contact with a flow of fluid flowing in a direction of flow relative to the body. Advantageously and according to the invention, the transducer is arranged with respect to the body so that its longitudinal direction is intersecting with the flow of fluid, and therefore with the direction of flow of the fluid relative to the body. Advantageously and according to the invention, this connection between the distal end and the body is adapted to rigidly fix the distal end relative to the body at least in any direction parallel to the direction of flow of the fluid relative to the body. Preferably, the assembly between the distal end and the body is adapted to rigidly attach the distal end to the body in any direction orthogonal to the longitudinal direction, i.e., to prevent any deformation in the longitudinal direction. bending of the transducer corresponding to a displacement of the distal end relative to the proximal end. Advantageously and according to the invention, each of the two axial ends of the tubular body is arranged to be coupled to rotate with a rod. In addition, advantageously and according to the invention, the tubular body can be adapted to be able to transmit forces - in particular the forces of rotation and / or longitudinal translation - between its two axial ends. Thus, a flowmeter according to the invention has a dual function: it not only acts as a flowmeter for measuring the flow of the fluid, but it also constitutes a force transmission member - in particular in rotation and / or in longitudinal translation- between a driven member and a driving member, for example a valve actuator and a valve shutter. The invention also extends to a valve comprising: - a body, - a shutter, - a control rod of the shutter, this control rod extending inside the body at least partly in a fluid flow zone, characterized in that the control rod comprises at least one flow meter in said fluid flow zone. It extends in particular to such a valve characterized in that the control rod comprises at least one flowmeter according to the invention. Advantageously, a valve according to the invention is also characterized in that the shutter is a rotary shutter and in that the flowmeter is adapted to be able to transmit rotational movements between an actuator of the valve and the shutter. To do this, advantageously and according to the invention a first axial end of the flowmeter is assembled to a driving member, and a second axial end of the flowmeter is assembled to a driven drive member of the shutter.
    [0006] In certain advantageous embodiments in accordance with the invention, a first axial end of the flow meter is assembled at one end of a first control rod, called a driving control rod, coupled to an actuator of the valve, and a second end. The axial flow of the flow meter is assembled at one end of a second control rod, called the driven control rod, coupled to the shutter. The assemblies between the actuator, the control rods, the flowmeter and the shutter form a mechanical transmission which makes it possible to control the displacements in position of the shutter under the effect of the operation of the actuator, and thus to control the flow of the fluid into the valve through the shutter by a simple rotation of the actuator. In addition, such a flowmeter can be assembled to any valve incorporating at least one tubular rod arranged in the valve to be in contact with a fluid. Furthermore, advantageously a valve according to the invention is also characterized in that at least the driving control rod is a tubular rod and in that said electrical connection of the flowmeter extends in the tubular driving control rod. Thus, the electrical connection of the flowmeter to the outside of the valve can be performed in a simple and reliable and secure without risk of damage or short circuit.
    [0007] In particular, a valve according to the invention is a fire hydrant. Advantageously and according to the invention, the rod and the flow meter are arranged in the body of the fire hydrant to facilitate assembly and maintenance of the flow meter. Indeed, the flowmeter is placed in the heart of an above-ground part (not buried) of the fire hydrant. This part of the fire hydrant can be dismantled from the rest of the fire hydrant body thus allowing simple access to the tubular control rod incorporating the flow meter and to the flow meter in the case of maintenance. Such an arrangement therefore does not require in particular to dig the ground to access the flowmeter. In addition, the flowmeter incorporated within the body of the fire hydrant is protected from external aggression and is secured.
    [0008] Other objects, features and advantages of the invention will become apparent on reading the following non-limiting description which refers to the appended figures in which: FIG. 1 is a schematic perspective view of a flowmeter 5 according to one embodiment of the invention, - Figure 2 is a schematic perspective and exploded view of the flow meter of Figure 1; - Figure 3 is a schematic axial sectional view of a fire hydrant; according to one embodiment of the invention incorporating a flowmeter 10 according to the invention, - Figure 4 is a schematic view of detail of Figure 3 showing more particularly the flow meter according to the invention - Figure 5 is a schematic view in perspective and exploded fire hydrant according to Figure 3.
    [0009] A flow meter 20 according to the invention is shown, according to a particular embodiment, in FIGS. 3 to 5 assembled with two rods inside a fire hydrant body. This flowmeter 20 comprises a substantially tubular generally straight body 21 extending axially in a main direction 23. This body 21 is formed by a tubular wall 22 delimiting a sealed enclosure 24, and 20 of which both ends 25, 26 are axially sealed. by plugs 27, 28. The tubular body 21 may be formed of any fluid-tight material whose flow rate must be measured, that is to say in particular watertight in the case of a fire hydrant. It may be in particular a stainless metal alloy, or a rigid polymeric synthetic material.
    [0010] Each end 25, 26 of the axial body 21 is arranged to be embedded in a tubular shaft whose one end abuts axially against a shoulder 75 outside the tubular wall 22. A first axial end has threaded holes 29 and the other axial end 26 has orifices 30 extending through the thickness of the tubular wall 22.
    [0011] This flowmeter also comprises two ultrasonic transducers 31 shown only schematically in the figures. Such an ultrasonic transducer is known per se and can be the subject of numerous variants. Each transducer 31 comprises a rigid shell enclosing the various components of the transducer and having a rigid main portion 32 elongate in a longitudinal direction of the transducer, a proximal end 33 and a distal end 34. The proximal end 33 is wider than the main portion 32 and is the widest part of the transducer 31. The distal end 34 is narrower than the main portion 32 and is the thinnest part of the transducer 31. Since the distal end 34 is narrower than the main portion 32 of the transducer, a distal shoulder 37 connects the lateral peripheral face 35 of the distal end 34 to the peripheral peripheral face 36 of the main portion 32 of the transducer. The proximal end 33 of each transducer 31 is placed inwardly of the tubular body 21 while the main portion 32 passes through the wall 22 of the body 38 and protrudes outwardly with respect to said tubular body 21, so that the active zone 38 of the transducer 31 and the distal end 34 of the transducer 31 are outside the tubular body. The two active zones 38 of the two transducers 31 are facing each other, aligned in a direction parallel to the main direction 23 of the tubular body 21, so that the ultrasonic waves emitted by the active zone 38 of the one of the transducers 31 are received by the active zone 38 of the other transducer 31. The tubular body 21 comprises two diametrically opposed orifices 39 passing through the thickness of the tubular wall 22 and in which the proximal ends 33 of the transducers are recessed. Each orifice 39 comprises an internal recess 40 opening inside the tubular wall 22 and adapted to receive the proximal end 33 of a transducer and an outer recess 41 of smaller width adapted to house a seal 42 in contact with each other. a shoulder of the proximal end 33. The proximal end 33 is held in the internal recess 40 by a washer 43 assembled inside the tubular wall 22 of the body 21 by screws 44, making it possible to compress the seal 42 and to fix the transducer 31 in longitudinal translation. in relation to the body 21.
    [0012] The device according to the invention also comprises an electronic card 45 in the sealed enclosure 24 formed inside the body 21. This electronic card 45 is adapted to form control signals of one of the transducers 31 (transmitter ultrasonic waves) and process the measurement signals 5 delivered by the other transducer 31 (receiving the ultrasonic waves). The electronic card 45 is connected to the outside of the sealed enclosure 24 by connection conductors 46, forming an electrical connection, passing through a fluid-tight passage, of the stuffing box type 47, of one of the 27 plugs. axial end of the tubular body 21 of the flow meter. The electronic card 45 is of generally rectangular shape and is placed on the two washers 43. The electronic card 45 is fixed to the tubular wall 22 with the washers 43 by the screws 44. The flowmeter according to the invention further comprises a stirrup 48 extending along and outside the body 21 between the two transducers 31 that it connects, and having a core 49 and two wings 50 whose ends 51 are fixed to the body 21 and flared to fit to the cylindrical shape of the outer face of the tubular wall 22 of the body 21. In the example shown, the stirrup 48 is assembled to the body 21 so that the wings 50 of the stirrup 48 are at least substantially parallel to the longitudinal direction of the transducers 31. The wings 50 are also parallel to the main direction of the tubular body 21 and are spaced from the transducers 31. The core 49 of the stirrup 48 is flat and orthogonal to the wings 50 and to the direction longitudinal transducers 31, and is parallel to the main direction of the tubular body 21. Nothing prevents the provision of other forms for the stirrup 48, for example with flanges 50 inclined with respect to this longitudinal direction and / or a core 49 with a curved transverse cross-section, or the like. The flared ends 51 of the flanges 50 are fixed to the tubular wall 22 of the body 21 by screws 52 clamped in threads 53 conjugated to the tubular wall 22. The core 49 of the stirrup 48 comprises two bores 54 traversing the thickness of the core 50 in which the distal ends 34 of the transducers 31 are inserted and inserted without radial play. In the variant shown, the shoulder 37 distal of the main portion 32 is in contact with the core 49 of the stirrup 48, each transducer 31 being locked in translation between the body 21 and the stirrup 48. In one embodiment, a fluid may flow out of the tubular body 21 in a direction of flow that may be parallel to the main direction of the tubular body. The fluid can thus flow into the space between said body 21 and the stirrup 48 where the two transducers 31 are placed. The tubular body 21 comprises two bores 56 traversing its wall 22 diametrically opposite the two receiving orifices 39. Transducers 31, for insertion of the transducers 31 inside the chamber 24. Two sealed plugs 55 are then placed in these bores 56. A flow meter according to this embodiment of the invention can be manufactured by performing the body 21 with the bores 56, the orifices 39 and the recesses 40, 41. Two transducers 31 and a stirrup 48 of conjugated dimensions are chosen. A seal 42 is placed in each external chamber 41 and then a transducer 31 is inserted through each bore 56 into the diametrically opposite orifice 39 until the proximal end 33 of the transducer 31 is embedded in the internal chamber 40. A washer 43 is then placed above each transducer 31 and an electronic card 45 above each washer 43 passing through one of the axial ends of the body 21. The whole of the electronic card 45 and the washer 43 by the screws 44 on the tubular wall 22 by means of a tool passed through the bores 56. The plugs 27, 28 are then assembled in the ends of the body 21 and the plugs 55 sealed in the bores 56.
    [0013] A flowmeter according to the invention can be integrated into any valve comprising a tubular control rod of a shutter placed in the valve, this tubular control rod being in contact with a fluid flow. The integration of such a flowmeter 20 in a fire hydrant 57 is shown in FIGS. 3 to 5. The fire hydrant 57 comprises a body having three distinct sections: an upper section 58 above ground, a section 59 subterranean intermediate but having an upper end 3035498 12 flush with the ground, and a section 60 of underground connection to a supply line of the fire hydrant under pressure water. The upper section 58 of the fire hydrant extends vertically in a direction defining a direction of flow in this upper section 58. The upper end of the upper portion 58 is surmounted by a cap 61 having an actuator 62. The actuator 62 is an operating member for opening or closing a shutter 70 placed between the intermediate section 59 and the section 60. fitting. This shutter 70 makes it possible to interrupt the circulation of water in the intermediate section 59 and the upper section 58 when it is closed by maneuvering the actuator 62. The shutter 70, on the contrary, makes it possible to open the circulation of water in the intermediate section 59 and in the upper section 58 when it is opened by actuation of the actuator 62. The actuator 62 is generally operated in rotation by means of a tool such as a conjugate key of this actuator 62.
    [0014] The upper section 58 also includes a plurality of lateral water intakes 63 through which the pressurized water may be delivered through the fire hydrant, and which allows the connection of fire equipment lines. The lower end of the upper section 58 is assembled at an upper end of the intermediate section 59. The lower end of the intermediate section 59 is assembled at an upper end of the coupling section 60. The lower end of the coupling section 60 is assembled to a pipe for supplying the fire hydrant 57 with water under pressure. The upper section 58 incorporates a driving control rod 64 extending inside the section 58 in the direction of the water flow, vertically along the axis of the upper section 58. The upper end 65 of the driving control rod 64 is coupled to the actuator 62 so as to be able to transmit the rotational movement exerted on the actuator 62 to the driving control rod 64. The lower end 66 of the drive control rod 64 is coupled to the axial end of the flowmeter 20 having the plug 27 incorporating the sealed bushing 47 for the electrical link 46.
    [0015] The flowmeter 20 is placed inside the upper portion 58 of the fire hydrant 57 so that the tubular body 21 extends in the direction of flow of the fluid. This arrangement thus allows easy access to the flowmeter during maintenance because the actuator 62 and the drive control rod 64 can be easily dismantled from the rest of the fire hydrant. The other end 26 of the flowmeter is coupled to the upper end 68 of a driven rod 67. Another lower end 69 of the driven control rod 67 is coupled to the shutter 70.
    [0016] Thus, the rotational movement exerted on the actuator 62 by an operator is transmitted to the shutter 70 via the driving control rod 64, the tubular body 21 of the flow meter, and the control rod 67 , which makes it possible to drive the shutter 70 in rotation relative to the body of the fire hydrant in order to control the flow of water in the upper section 58 and in the intermediate section 59. In the embodiment shown, the assembly of the axial end of the flowmeter with the lower end 66 of the driving control rod 64 is formed by screws 71 each passing through a bore 72 of the end of the rod 64. The axial end of the flow meter with the upper end 68 of the driven control rod 67 is formed by a pin and is screwed into a threaded hole 29 of the axial end of the flowmeter. (Not shown in the figures) introduced radially into orifices 74 passing radially through the upper end 68 of the lower rod 67 and the orifices 30 opposite the axial end 26 of the flowmeter. These two assemblies make it possible to keep the tubular rods 64, 67 in contact with the shoulders 75 of the flowmeter. A seal (not shown) may be interposed between the shoulders 75 and the ends of the control rods to seal. Similarly, a seal (not shown) may be provided at the coupling screws 71 and / or the coupling pin of the tubular control rods to the tubular body 21 of the flow meter.
    [0017] The electrical connection 46 of the flowmeter extends in the upper driving control rod 64 to the cap 61, the latter being able to be provided with a connector for connecting an external electrical equipment (not shown) or an electronic circuit for transmitting data remotely, for example by radio frequency with a remote monitoring station. Thus, the electrical connection is not in contact with the fluid. The invention can be the subject of numerous variants with respect to the embodiments described above and shown in the figures. In particular, the body of the flow meter carrying the transducers may not be generally tubular. The axial ends of the flowmeter and the control rods may not be tubular, since they have conjugated assembly means for coupling them in rotation and / or in translation for controlling the movements of the shutter under the effect of operating the actuator of the valve. There may also be several flowmeters inserted along the shutter control rod of the valve. Maintaining the axial end 26 of the flowmeter with the end 68 of the driven control rod 67 can also be achieved not by a pin, but by screws introduced into two diametrically opposed bores of the control rod 67 conducted and screwed into two threaded holes in the axial end of the flowmeter. Alternatively or in combination, nothing prevents assembling the ends of the flow meter with one and / or the other of the two control rods by any other means of coupling, for example by gluing or welding. According to another possible embodiment, not shown, of a valve according to the invention, the tubular body of the flowmeter itself constitutes a control rod equal in length to the original control rod of the fire hydrant. In other words, the control rod of the fire hydrant can itself be modified to act as a tubular body of the flow meter according to the invention. In this embodiment, the stirrup is assembled to the control rod. The bores, used to introduce the transducers and surmounted by sealed plugs, as well as the chamberings are then machined in the control rod. According to another possible embodiment, not shown, of a valve according to the invention, an axial end of the flowmeter placed inside the valve 5 is directly coupled to the actuator of the valve. The other axial end of the flow meter is then connected to a driven control rod coupled to the shutter of the valve. The flowmeter must then be arranged so that the active zone of the transducers can be in contact with the flow of fluid towards one and / or the other of the intakes.
    [0018] According to another possible embodiment, not shown, of a valve according to the invention, an axial end of the flowmeter placed inside the valve is coupled to a driving control rod coupled to the actuator of the valve, while the other axial end of the flowmeter is coupled directly to the shutter of the valve. Again, the flowmeter should be arranged so that the active area of the transducers can be in contact with the fluid flow. The invention may also be the subject of other applications than for a fire hydrant, and for which the same problems arise. 20
    权利要求:
    Claims (6)
    [0001]
    CLAIMS1 / - Flow meter comprising: - a body (21) having two axial ends tubular - a flow measurement device carried by the tubular body - an electrical connection (46) extending outside the tubular body, characterized in that: - the flow measuring device is associated with the tubular body (21) so as to allow measurement of a flow of fluid flowing outside the tubular body (21), - said electrical connection ( 46) passes through the tubular body by at least one fluid-tight passage.
    [0002]
    2 / - Flowmeter according to claim 1, characterized in that the tubular body (21) is fluid-tight and contains at least one electronic circuit (45) of the flow measurement device.
    [0003]
    3 / - flow meter according to one of claims 1 to 2, characterized in that at least one (25) of the axial ends (25, 26) of said body (21) comprises a tubular fluid-tight passage.
    [0004]
    4 / - flow meter according to one of claims 1 to 3, characterized in that said flow measuring device comprises at least one ultrasonic transducer (31) extending outside said body (21) tubular.
    [0005]
    5 / - Flow meter according to claim 4 characterized in that: - said body (21) is a tubular tubular body extending along an axis passing through the two axial ends (25, 26), - each ultrasonic transducer (31) is orthogonal to the axis of said tubular body (21).
    [0006]
    6 / - flow meter according to one of claims 4 or 5, characterized in that it comprises a stirrup (48) for assembling a distal end (34) of each transducer (31) to said body (21) tubular. 7 / - Flow meter according to one of claims 1 to 6, characterized in that each of the two axial ends (25, 26) of the body (21) is arranged to be coupled to a rotationally integral with a rod. 8 / - Valve comprising: 5 - a body (58, 59, 60), - a shutter (70), - a control rod of the shutter, this control rod extending inside the body at least partly in a fluid flow zone, characterized in that the control rod comprises at least one flowmeter (20) according to one of claims 1 to 7 in said fluid flow zone. 9 / - Valve according to claim 8, characterized in that the shutter (70) is a rotary shutter and in that the flowmeter (20) is adapted to be able to transmit rotational movements between an actuator (62) of the valve and the shutter (70). 10 / - valve according to one of claims 8 or 9, characterized in that a first end (25) of the axial flowmeter is assembled to a driving member, and a second end (26) of the axial flowmeter is assembled to an organ driven shutter drive (70). 20 11 / - Valve according to one of claims 8 to 10, characterized in that a first end (25) of the axial flowmeter (20) is assembled at one end (65) of a first control rod, called rod (64), coupled to an actuator (62) of the valve, and a second axial end (26) of the flow meter (20) is assembled at one end (68) of a second control rod (67). said driven control rod (67) coupled to the shutter (70). 12 / - Valve according to claim 11, characterized in that at least the driving control rod (64) is a tubular rod and in that said electrical connection (46) of the flowmeter extends in the rod (64) of tubular driving control 30. 3035498 18 13 / - Valve according to one of claims 8 to 12 characterized in that it is a fire hydrant.
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    同族专利:
    公开号 | 公开日
    CN107532934B|2020-01-07|
    WO2016170270A1|2016-10-27|
    US10401205B2|2019-09-03|
    EP3286529A1|2018-02-28|
    US20180136025A1|2018-05-17|
    EP3286529B1|2020-03-04|
    FR3035498B1|2020-04-24|
    CN107532934A|2018-01-02|
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    US8967277B2|2011-06-03|2015-03-03|Halliburton Energy Services, Inc.|Variably configurable wellbore junction assembly|
    CN203412037U|2013-07-30|2014-01-29|西安大盛消防检测有限公司|Automatic-alarm fire hydrant|
    FR3035498B1|2015-04-23|2020-04-24|Integra Metering Sas|FLOW METER FOR MEASURING A FLUID FLOW RATE OUTSIDE A TUBULAR BODY AND VALVE INCORPORATING IT|FR3035498B1|2015-04-23|2020-04-24|Integra Metering Sas|FLOW METER FOR MEASURING A FLUID FLOW RATE OUTSIDE A TUBULAR BODY AND VALVE INCORPORATING IT|
    US20190177955A1|2017-12-08|2019-06-13|Prestigious Innovations, LLC|Hydrostatic pressure washer|
    CN112741978A|2020-12-31|2021-05-04|新疆中睿电子科技有限公司|Fire hydrant monitoring and management system|
    法律状态:
    2016-04-22| PLFP| Fee payment|Year of fee payment: 2 |
    2016-10-28| PLSC| Search report ready|Effective date: 20161028 |
    2017-04-18| PLFP| Fee payment|Year of fee payment: 3 |
    2018-04-27| PLFP| Fee payment|Year of fee payment: 4 |
    2018-06-22| CD| Change of name or company name|Owner name: INTEGRA METERING SAS, FR Effective date: 20180517 |
    2019-04-18| PLFP| Fee payment|Year of fee payment: 5 |
    2020-04-20| PLFP| Fee payment|Year of fee payment: 6 |
    2021-04-23| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1553673A|FR3035498B1|2015-04-23|2015-04-23|FLOW METER FOR MEASURING A FLUID FLOW RATE OUTSIDE A TUBULAR BODY AND VALVE INCORPORATING IT|
    FR1553673|2015-04-23|FR1553673A| FR3035498B1|2015-04-23|2015-04-23|FLOW METER FOR MEASURING A FLUID FLOW RATE OUTSIDE A TUBULAR BODY AND VALVE INCORPORATING IT|
    CN201680022932.3A| CN107532934B|2015-04-23|2016-04-20|Valve comprising a flow meter for measuring the flow of a fluid inside the valve|
    PCT/FR2016/050923| WO2016170270A1|2015-04-23|2016-04-20|Valve incorporating a flowmeter for measuring a flow of fluid inside same|
    EP16721461.8A| EP3286529B1|2015-04-23|2016-04-20|Valve incorporating a flowmeter for measuring a flow of fluid inside same|
    US15/567,135| US10401205B2|2015-04-23|2016-04-20|Valve incorporating a flowmeter for measuring a flow of fluid inside same|
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