• 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 hysteresis fluidic valve (10) comprises: - a valve (26) adapted to take at least one closed position and an open position, - a piston (30) sensitive to the flow of fluid capable of taking at least one low flow position and a high flow position. The valve (26) and the piston (30) are arranged such that as long as the piston (30) is in a high flow position, the valve (26) is prevented from occupying the closed position.
    公开号:FR3042576A1
    申请号:FR1559775
    申请日:2015-10-14
    公开日:2017-04-21
    发明作者:Bernard Balet
    申请人:SELFFLOW PACIFIC;
    IPC主号:
    专利说明:

    The invention relates to valves for the passage of a fluid. The invention also relates to soil irrigation.
    In order to direct the flow of a fluid in a system comprising several ducts, it is known to use a valve electrically controlled by conduit and an electric programmer.
    Thus, the electric programmer is able to move the electrically controlled valves from a closed position to an open position and vice versa. The programmer can therefore direct the flow of fluid into the system.
    For example, in the case of agricultural soil that is to be watered, such soil is usually divided into at least two successive distinct zones with respect to the flow of available water. Two ducts, supplied with water, are thus installed in bypass from a main duct. An electrically controlled valve, or solenoid valve, is also installed between the main duct and each outlet of the bypass ducts. Then install an electric programmer able to close and open the solenoid valves.
    To sequentially water each zone, the programmer opens a solenoid valve, while keeping the other solenoid valve closed. So, we periodically water plots of agricultural soil. The electrical connection between the electric programmer and the solenoid valve is most often done by means of at least one electrical wire.
    However, the operating conditions of an agricultural or horticultural operation, and more generally the wet environment in which such a system operates, can damage the electrical wires and deteriorate the quality of the electrical connection between each electric programmer and its solenoid valve. In addition, it is necessary to supply electrical power to the programmer and the solenoid valve. Finally, the use of electrical wires prevents the programmer and the solenoid valve from being positioned at a distance of more than a few tens of meters, except to provide long electrical connections that would further reduce the reliability of the system.
    In addition, in general, the use of electrical son and more generally of electric current is poorly adapted to the presence of fluid, especially liquid.
    An object of the invention is therefore to provide a valve that can be controlled without using electrical energy.
    To this end, according to the invention, a hysteresis fluidic valve is provided, comprising: a valve capable of taking at least one closed position and an open position; a piston sensitive to the flow of fluid capable of taking at least one low flow position and a high flow position, characterized in that the valve and the piston are arranged so that as the piston is in the high flow position, the valve is prevented from occupying the closed position.
    Thus, by fluidly controlling the piston sensitive to the fluid flow, it is possible to control the position of the valve and thus the opening or closing of the hysteresis fluidic valve. In addition, since the piston sensitive to the fluid flow is able to maintain the valve in the open position, it is possible to establish a valve opening condition different from the closed condition. This confers the hysteretic character to the valve and allows, in the case of several valves installed on the same network, to prioritize the opening of a valve to the detriment of others.
    Preferably, the flow responsive piston includes a bearing surface for the valve to maintain the valve in the open position. The size of the valve is reduced.
    Advantageously, the valve comprises means adapted for the valve to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold.
    According to one embodiment, the means adapted for the valve to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold comprise at least one piston, a seal and preferably a spring and a button. screwed.
    Preferably, the means adapted for the valve to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold comprise at least one membrane.
    These are simple ways to configure the pressure threshold.
    Advantageously, the valve comprises means adapted so that the flow sensitive piston is in the high flow position when the fluid pressure exceeds the predetermined threshold and an outlet of the valve is in a fluid flow position.
    Preferably, the valve comprises means adapted so that the flow-sensitive piston remains in the high flow position when the fluid pressure has dropped below the predetermined threshold as long as the outlet of the valve remains in the fluid passage position.
    This is a simple way to set up the hysteresis of the valve.
    According to one embodiment, the valve comprises a spring for keeping the piston responsive to the flow in low flow position.
    The invention also provides a hysteresis fluidic control valve comprising: a fluidic control valve having a main duct and a control output, and a hysteresis fluidic valve as previously described, connected to the control output of the fluidic control valve.
    Thus, the opening and closing of the fluidic control valve can be controlled by means of the hysteresis valve.
    According to the invention, provision is made for a hysteresis fluidic control comprising: a hysteresis fluidic valve as previously described, and a fluidic control connected to the output of the hysteresis fluidic valve.
    Thus, it is possible to control the hysteresis fluidic valve by means of a fluidic control. The hysteresis fluidic valve is therefore controlled by the fluid demands of the zone to be fed with fluid.
    Finally, according to the invention, there is provided a fluid supply system comprising: at least one fluidic control valve with hysteresis as previously described, at least one fluidic control with hysteresis as previously described, characterized in that the hysteresis fluidic control valve and the hysteresis fluidic control comprise a common hysteresis fluid valve.
    Two embodiments of the invention will now be described in a nonlimiting manner with the aid of the following figures: FIG. 1 is an exploded sectional view of a hysteresis fluidic valve according to an embodiment of the invention. 2 to 5 are sectional views of this valve in different open and closed positions; FIG. 6 is a sectional view of a valve according to a second embodiment of the invention; Fig. 7 is a sectional view of a hysteresis fluidic control valve, and Fig. 8 is a sectional view of a hysteresis fluidic control according to the invention.
    FIGS. 1 and 2 show a hysteresis fluidic valve 10 according to the invention.
    Throughout the description, the terms "flow" and "flow" are used indifferently, which are considered synonymous in the context of the invention.
    The hysteresis fluidic valve 10 comprises a body 11, formed of a stack 11a, which is here generally cylindrical, provided at its base with a fluid inlet channel 12 and a fluid outlet channel 14. Here, the inlet channel 12 and the fluid outlet channel 14 are in the same axis, perpendicular to that of the chimney 11a. The hysteresis fluidic valve 10 is therefore a straight body valve. According to a variant of this embodiment, the hysteresis fluidic valve 10 comprises a corner body.
    The hysteresis fluidic valve 10 also comprises, housed in the chimney 11a, a first piston 16, a seal member 18, a first spring 20 and a knob 22, screwed on the chimney 11a around the first spring 22, which extend along the axis of the chimney 11a, that is to say here perpendicular to a direction of fluid flow between the inlet 12 and the fluid outlet 14. The body 11 comprises a fluid circulation chamber 24, one end of which forms the seat of the seal 18, as can be seen in particular in FIG. 2, in order to prevent the fluid coming from the fluid inlet 12d. reaching the fluid outlet 14 when said seal 18 rests on its seat.
    Here, the first piston 16, the seal 18, the first spring 20 and the button 22 form, with the fluid circulation chamber 24 of the body 11, a valve 26 adapted to take at least one closed position, visible at 2, and an open position, visible in particular in Figure 3. By more or less tightening the knob 22 on the shaft 11a around the first spring 20 which bears on the first piston 16, the spring tension is defined and therefore a pressure threshold in fluid higher or lower from which the fluid passes through the valve.
    When the pressure of the fluid at the inlet 12 is below this threshold, the first spring 20 bears on the first piston 16 and applies the seal 18 against the end of the fluid circulation chamber 24 of the body 11, so as to maintain the valve 26 in the closed position, as seen in Figure 2. In contrast, when the fluid pressure at the inlet 12 exceeds this predetermined threshold, the first spring 20 is compressed by the fluid. The seal 18 then no longer rests against the end of the fluid circulation chamber 24 of the body 11. The fluid can therefore flow from the fluid inlet 12 to the fluid outlet 14, as illustrated in Figure 3. The valve 26 is then in the open position.
    Thus, the hysteresis fluidic valve 10 comprises means adapted for the valve 26 to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold. Here, these means comprise the first piston 16, the seal 18, the first spring 20 and the button 22.
    Note that the first piston 16 comprises a pin 16a which performs two functions: on the one hand, it holds the seal 18 in an annular groove 16b at its base, on the other hand, it occupies a volume in the fluid circulation chamber. This latter function will be explained in relation to a second piston 30 of the hysteresis fluidic valve 10.
    Indeed, the hysteresis fluidic valve 10 comprises a second spring 28 and a second piston 30, housed in the inlet channel 12. The inlet channel 12 comprises two sections: an upstream section 12a and a further downstream section 12b small diameter than the upstream section 12a, separated by a shoulder 12c.
    The second piston 30 is a hollow cylindrical body, that is to say a longitudinal inner channel, having a bottom 34 at one of its ends and an outer flange 32 at its opposite end. The bottom 34 is placed downstream in the fluid flow direction, while the collar 32, around the open end, is placed upstream. As can be seen in particular in FIG. 2, the second spring 28 is engaged around the second piston 30 and the outer collar 32 serves as a seat for the second spring 28. The opposite end of the second spring 28 bears on the shoulder 12c of the inlet channel 12. Near the bottom 34, the second piston 30 comprises a plurality of orifices 36 whose role will be described later.
    The hysteresis fluidic valve 10 comprises a tip 38 which serves two functions: externally, it serves as a connection for a pipe (not shown) connected to the hysteresis fluidic valve, internally it serves as a stop on the outer flange 12 of the second piston to maintain the latter in the body. The tip 38 is hollowed out of a longitudinal channel which extends the longitudinal inner channel of the second piston.
    The second piston 30 is movable by axial translation in the body 11, between two end positions, according as its outer flange 12 is supported on the end piece 38 or the second spring 28 compressed against the shoulder 12c.
    Because the outer diameter of the second piston 30 is slightly less than the inner diameter of the conduit which surrounds it, the second piston 30 leaves around it a clearance which allows the fluid to pass through it whatever its position. The second piston therefore never prevents the passage of the fluid entering the valve through the fluid inlet 12.
    Thus, the second piston 30 transmits to the first piston 16 the pressure of the fluid present in the inlet channel 12.
    Due to its configuration, the second piston 30 is sensitive to the flow rate of the fluid passing through the inlet channel 12.
    Indeed, as the fluid flow rate is below a threshold defined by the calibration of the second spring 28, the second piston is in a detent position that can be seen in particular in Figures 2 and 3.
    When the fluid flow rate exceeds the predetermined threshold, the second piston 30 is driven downstream and compresses the second spring 28, as shown in Figure 4. In this case, the fluid from the fluid inlet 12 s' flows directly into the fluid circulation chamber 24 through the orifices 36. The pressure losses are thus reduced and the passage of the fluid is thus further facilitated, which tends to maintain or increase its flow.
    When the second piston 30 is in its high flow position, it occupies part of the internal volume of the fluid circulation chamber 24, chamber in which the stud 16a of the first piston 16 is also housed.
    Thus, the second piston 30 is sensitive to the fluid flow and is capable of taking at least one low flow position and one high flow position. In addition, the hysteresis fluidic valve 10 comprises suitable means, here the second spring 28, for the piston 30 sensitive to the flow is in the high flow position when the fluid flow exceeds the predetermined threshold.
    In addition, even if the fluid pressure drops below the predetermined pressure threshold, as long as the fluid outlet 14 of the hysteresis fluidic valve 10 is open and the flow rate is sufficient, the piston 30 is held in the flow position. Student. This is because when the fluid is flowing at a high rate, it maintains the second compressed spring 28.
    So that the second spring 28 returns to the detent position, it is necessary that the fluid flow back down, and regardless of the pressure of the fluid.
    The operation of the hysteresis fluidic valve 10 will now be described with reference to FIGS. 2 to 5.
    The hysteresis fluidic valve 10 is intended to receive all types of fluid, namely a gas or a liquid. In this embodiment, the hysteresis fluidic valve 10 is for receiving a liquid such as water.
    When the fluid pressure is below a predetermined threshold, the hysteresis fluidic valve 10 is in its position shown in FIG. 2. The valve 26 is in the closed position, which has the consequence that the fluid flow rate is zero and that the second piston 30 is in the low flow position.
    Thus, as long as the fluid pressure at the inlet of the hysteresis fluidic valve 10 is less than the predetermined threshold, the fluid can not reach the fluid outlet 14 of the hysteresis fluidic valve 10.
    When the fluid pressure exceeds the predetermined threshold but the fluid outlet 14 is closed, for example because another valve (not shown), located downstream, is closed, the hysteresis fluidic valve 10 takes the position shown in FIG. Figure 3. The valve 26 is in the open position, but the piston 30 is still in the low flow position since the fluid does not flow. The fluid occupies the fluid circulation chamber 24 but can not leave the hysteresis fluidic valve 10.
    When the fluid pressure exceeds the predetermined threshold and the fluid outlet 14 is open, the hysteresis fluid valve 10 assumes the position shown in FIG. 4. The valve 26 is in the open position and the second piston 30 is in the position high flow rate.
    When, for example because of the opening of the fluid outlet 14, the fluid pressure drops below the predetermined pressure threshold, the hysteresis fluidic valve 10 takes the position shown in FIG. 5. The second piston 30 is always in the high flow position because the fluid outlet 14 is open. Thus, as the second piston 30 responsive to the fluid flow occupies part of the fluid circulation chamber 24, it gene the descent of the piston 30, the pin 16a can not enter sufficiently into said chamber 24. In other In other words, the second piston comprises a surface which forms a support for one end of the first piston 16, namely here the stud 16a, and the first piston 16 can not apply the seal 18 on the complementary end of the chamber. fluid circulation 24. Thus, the valve 26 is held in the open position.
    The valve 26 and the piston 30 are thus arranged so that as the piston 30 is in the high flow position, the valve 26 is prevented from occupying the closed position.
    In order for the hysteresis fluidic valve 10 to return to the position shown in FIG. 2, the fluid outlet 14 must be closed.
    Thus, even when the fluid pressure has fallen below the threshold, the fluidic valve 10 is open as long as the fluid outlet 14 is not closed. This is why it can be qualified as a hysteresis 10 fluidic valve.
    Moreover, since it is the closure of the fluid outlet 14 which determines the end of the fluid flow in the hysteresis fluidic valve 10, the flow ends when the device located downstream of the hysteresis fluidic valve 10 no longer requires fluid.
    An advantageous use of the valve according to the invention consists in placing at least two hysteresis fluidic valves on two parallel ducts fed by a main duct. Thanks to the two fluidic hysteresis valves, it is possible to prioritize the supply of one of the ducts. Indeed, by more or less tightening the knob 22, a higher or lower pressure threshold is defined and it is determined which of the two valves will open first.
    When the pressure exceeds the predetermined threshold in the two valves but only the fluid outlet 14 of one of the hysteresis fluidic valve 10 is open, the piston 30 sensitive to the flow of the latter goes into a high flow position and thus prevents the flap 26 to occupy the closed position. Thus, even if the pressure drops in the main duct due to the high flow rate in one of the hysteresis fluidic valves 10, it will remain in the high flow position while preventing the opening of the fluid outlet. In fact, by flowing the fluid, the open hysteresis fluidic valve 10 will keep the pressure in the main duct at a low level. Therefore, the other hysteresis fluidic valve 10 can have its fluid outlet 14 which passes to the open position only when the first hysteresis fluidic valve 10 has closed its fluid outlet 14.
    FIG. 6 shows a hysteresis fluidic valve 100 according to a second embodiment. Only differences with the first mode will be described. Unchanged elements retain the same numeric references.
    Here, the seal 18 has been replaced by a reinforced waterproof membrane 118. The piston 116 has a shape slightly different from that of the piston 16 but has the same functional parts. The same applies to the button 122. Thus, in this embodiment, the means adapted for the valve to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold comprise the membrane 118, the piston 116 , the spring 20 and the button 122.
    Here, the second piston 130 comprises a downstream section 134 whose diameter is greater than that of an upstream portion of the piston body 130. Thus, when the latter is in low flow position, the clearance between the downstream portion 134 of the piston and the downstream section 12b of the inlet channel 112 is minimal. Conversely, when the piston 130 is in the high flow position, the clearance between the upstream portion of the piston 130 and the downstream section 12b of the inlet channel 12 is larger, which allows higher fluid flow rates. Here, the piston 130 does not include orifices 36 for fluid circulation.
    In addition, the screwed knob 122 and the chimney 111a comprise complementary stops respectively 122a and 111b so as to define a maximum pressure threshold, for example to preserve the integrity of the hysteresis fluidic valve 100. Indeed, when the stops complementary 122a and 111b come into contact with one another, it is no longer possible to tighten the screwed knob 122 around the first spring 20.
    In addition, in this embodiment, a connection piece 114a is disposed in the fluid outlet channel 114 of the body 111 for example to connect the hysteresis fluidic valve 100 to a suitable fluidic device (not shown).
    There is shown in Figure 7 a fluidic control valve hysteresis 200.
    The hysteresis fluidic control valve 200 comprises a fluidic control valve 202. This fluidic control valve 202 includes a body 204 which here forms a main fluid conduit. The main fluid duct comprises an upstream duct 206 and a downstream duct 208. A sealed membrane 210 is disposed between the upstream duct 206 and the downstream duct 208. A spring 212 pushes the waterproof membrane back against its seat. In addition, the fluidic control valve 202 comprises, disposed in parallel with the upstream duct 206, a duct 214 which leads to a chamber 216 defined by the leaktight membrane 210 and in which the spring 212 is disposed. In addition, the duct 214 is connected to a control output 218 of the fluidic control valve 202.
    The hysteresis fluidic valve 10 is connected to the control output 218 of the fluidic control valve 202. As a result, the hysteresis fluidic valve is subjected to the pressure of the fluid present in the upstream conduit 206, at least as long as the output of the hysteresis fluidic valve is closed. The adjustment of the cap of the fluidic valve with hysteresis must be such that the pressure of the fluid in the upstream conduit 206 is sufficient to open the valve of the latter.
    As long as the fluid outlet 14 of the hysteresis fluidic valve 10 is closed, the fluid coming from the upstream duct 206 passes through the duct 214 and rejoins the chamber 216, where its pressure on the waterproof membrane ensures that the latter remains on its seat and, consequently, the closing of the fluidic control valve 202.
    When the fluid outlet 14 of the hysteresis fluidic valve 10 opens, the pressure of the fluid in said hysteresis fluidic valve drops, but as the flow sensitive piston has moved downstream to accompany the increase in flow rate. fluid flow, the hysteresis fluidic valve remains open.
    The drop in fluid pressure propagates to the chamber 216. The pressure of the fluid on the membrane, on the side of the inlet channel 206, then becomes greater and the membrane is detached from its seat. The fluid coming from the upstream duct 206 can therefore join the downstream duct 208.
    Thus, the circulation of fluid in the fluidic control valve 202 depends on the fluid flow in the hysteresis fluidic valve 10.
    FIG. 8 schematically shows a hysteresis fluidic control 300. The hysteresis fluidic control 300 comprises the hysteresis fluidic valve 10 as previously described and a fluidic control 302 connected to the fluid outlet 14 of the Hysteresis fluidic valve 10. In this embodiment, the fluidic control 302 is a valve. According to variants, the fluidic control 302 is an autonomous watering control device that is able to open and close when the device calculates that it is necessary to proceed with a watering.
    In order to form a fluid supply system, a hysteresis fluidic valve 10 is used which is part of both a hysteresis fluidic control 300 as previously described and a hysteresis fluidic control valve 200 also such that previously described.
    Of course, we can bring to the invention many variants without departing from the scope thereof.
    For example, it is possible to use all types of buttons to define the predetermined pressure threshold of the valve 26.
    It will also be possible to associate the hysteresis fluidic valve 10 with all types of fluidic device.
    权利要求:
    Claims (11)
    [1" id="c-fr-0001]
    1. Hysteresis fluidic valve (10), comprising: - a valve (26) adapted to take at least one closed position and an open position, - a piston (30) sensitive to the flow of fluid capable of taking at least one flow position low and a high flow position, characterized in that the valve (26) and the piston (30) are arranged such that as long as the piston (30) is in the high flow position, the valve (26) is prevented from occupy the closed position.
    [2" id="c-fr-0002]
    2. Valve (10) according to the preceding claim, wherein the piston (30) responsive to the flow comprises a bearing surface for the valve (26) to maintain the valve (26) in the open position.
    [3" id="c-fr-0003]
    A valve (10) as claimed in any one of the preceding claims comprising suitable means (16, 18, 20, 22, 116) for the valve (26) to move from the closed position to the open position when the pressure fluid exceeds a predetermined threshold.
    [4" id="c-fr-0004]
    4. Valve (10) according to the preceding claim, wherein the means adapted for the valve (26) to go from the closed position to the open position when the fluid pressure exceeds a predetermined threshold comprise at least one piston (16), a seal (18) and preferably a spring (20) and a screwed knob (22).
    [5" id="c-fr-0005]
    5. Valve (10) according to claims 3 or 4, wherein the means adapted for the valve (26) to move from the closed position to the open position when the fluid pressure exceeds a predetermined threshold comprise at least one membrane (116). ).
    [6" id="c-fr-0006]
    The valve (10) according to any one of the preceding claims, comprising means adapted for the flow sensitive piston (30) to be in a high flow position when the fluid pressure exceeds the predetermined threshold and an output (14) ) of the valve (10) is in a fluid flow position.
    [7" id="c-fr-0007]
    7. Valve (10) according to the preceding claim, comprising means adapted for the piston (30) sensitive to the flow remains high flow position when the fluid pressure has dropped below the predetermined threshold as the output (14) of the valve (10) remains in the fluid flow position.
    [8" id="c-fr-0008]
    8. Valve (10) according to any one of the preceding claims, comprising a spring (28) for maintaining the piston (30) sensitive to the flow in low flow position.
    [9" id="c-fr-0009]
    A hysteresis fluidic control valve (200) comprising: - a fluidic control valve (202) having a main conduit (204) and a control output (218), and - a hysteresis fluidic valve (10) according to the present invention. any of the preceding claims connected to the control output (218) of the fluidic control valve (202).
    [10" id="c-fr-0010]
    A hysteresis fluidic control (300) comprising: - a hysteresis fluidic valve (10) according to any one of claims 1 to 8, and - a fluidic control (302) connected to the outlet (14) of the fluidic valve hysteresis (10).
    [11" id="c-fr-0011]
    A fluid supply system comprising: - at least one hysteresis fluidic control valve (200) according to claim 9, - at least one hysteresis fluidic control (300) according to claim 10, characterized in that the valve fluidic hysteresis control (200) and hysteresis fluid control (300) comprise a common hysteresis fluid valve (10).
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    法律状态:
    2016-10-26| PLFP| Fee payment|Year of fee payment: 2 |
    2017-04-21| PLSC| Publication of the preliminary search report|Effective date: 20170421 |
    2017-06-02| CD| Change of name or company name|Owner name: AQUALONE, FR Effective date: 20170428 |
    2017-10-25| PLFP| Fee payment|Year of fee payment: 3 |
    2018-10-26| PLFP| Fee payment|Year of fee payment: 4 |
    2019-10-30| PLFP| Fee payment|Year of fee payment: 5 |
    2020-10-30| PLFP| Fee payment|Year of fee payment: 6 |
    2021-10-28| PLFP| Fee payment|Year of fee payment: 7 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1559775A|FR3042576B1|2015-10-14|2015-10-14|FLUID VALVE HYSTERESIS|
    FR1559775|2015-10-14|FR1559775A| FR3042576B1|2015-10-14|2015-10-14|FLUID VALVE HYSTERESIS|
    EP16793964.4A| EP3362716A1|2015-10-14|2016-10-14|Fluid valve with hysteresis|
    US15/768,721| US20180266576A1|2015-10-14|2016-10-14|Fluid Valve With Hysteresis|
    PCT/FR2016/052662| WO2017064438A1|2015-10-14|2016-10-14|Fluid valve with hysteresis|
    CN201680072777.6A| CN108368946A|2015-10-14|2016-10-14|Lag formula Fluid valve|
    MA042993A| MA42993A|2015-10-14|2016-10-14|HYSTERESIS FLUIDIC VALVE|
    IL258562A| IL258562D0|2015-10-14|2018-04-09|Fluid valve with hysteresis|
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