法国专利FR3020841A1 END LIMIT HOLDER FOR PISTON PRESSURE CONVERTER

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专利摘要:
The limit valve (1) for a piston pressure converter (2), the emitting cylinder (3) and the receiving cylinder (4) respectively defining an emitter chamber (9) and a receiving chamber (10), comprises a an expansion emitter cylinder (12) which communicates with the receiving chamber (10) and in which a motor-emitter piston (14) mechanically connected by a progressive-action lever transmission (11) to a pump piston can be moved; expansion receiver (15) which can move in an expansion receiver cylinder (13), said transmission (11) being provided so that when the engine-emitter piston (14) is at the top dead center the pump-receiver piston the trigger (15) is at the bottom dead center and vice versa, while a trigger release actuator (30) is able to move said transmission (11).
公开号:FR3020841A1
申请号:FR1455710
申请日:2014-06-20
公开日:2015-11-13
发明作者:Vianney Rabhi
申请人:Vianney Rabhi；
IPC主号:

专利说明:

[0001] The present invention relates to an end-of-stroke regulator for a piston pressure converter. The amplifiers or piston pressure reducers generally consist of at least one emitter cylinder in which an emitting piston rigidly connected to at least one receiving piston can move which can move in a receiving cylinder, the two said pistons moving on the piston. same race but presenting different section. Each said piston is driven by a cylinder and a cylinder head to form a closed and sealed space of variable size. The emitter cylinder communicates: -10C a hy ».aulic circuit independent of that of the receiver cylinder.
[0002] Piston amplifiers or pressure reducers can be used statically to maintain two circuits or two volumes independent of one another at a constant pressure ratio without necessarily establishing a flow of hydraulic fluid which involves the displacement of the emitter piston and the receiver piston. In the case of piston pressure amplifiers which convert a hydraulic fluid flow rate to a smaller but higher hydraulic fluid flow rate, or in the case of reciprocating pressure reducers or converters converting a hydraulic fluid flow rate to a flow rate of larger hydraulic fluid but under lower pressure, the emitter piston is a hydraulic motor that converts a flow of hydraulic fluid in motion, said movement being communicated to the receiving piston which forms a hydraulic pump so as to transform '...' 7H_Ivement in flow of hydraulic fluid. To increase the pressure, the emitter piston must be larger than the receiving piston, while to reduce the pressure, the emitter piston must have a smaller section than the receiver piston. It is noted in this case that the emitter cylinder comprises at least one inlet and at least one outlet which can each be held open or closed by valve while the receiving cylinder has at least one inlet which comprises a non-return valve allowing the hydraulic fluid to enter said cylinder but not out, and at least one outlet which has a non-return valve pere -Liant hydraulic fluid out of said cylinder but not entrc ;, When a flow settles durably through said amplifiers or piston reducers, the operation of the latter is sequential because when the pistons they comprise arrive at the end of the race, they must return to the start of the race and vice versa, and this for as long as said amplifiers or reducers. sequential operation is responsible for undesirable energy losses due to the compressibility of the flyaulic fluid, said losses being proportionally all the more important that said fluid is compressible and the pressures implemented are high. At the same operating pressures, said losses are proportionally greater ... if it is a pressure reducer, said losses occurring mainly at the cylinder emitter of said reducer, In practice, for pressures of a few tens or hundreds of barrels, the efficiency of amplifiers or piston pressure reducers remains high. When the latter are used at even higher pressures - for example of the order of a thousand bars or more - the compression ratio of the hydraulic fluid is increased which further deteriorates the said .. ndem .. r-rIrrô when are used fluids which are not very compressible, such as oil or calf. In fact, energy is locked during the compression of the hydraulic fluid, but said energy is usually lost at the end of the piston stroke, mainly on the side of the emitter piston. is due to the fact that when said piston reaches the end of the stroke, the emitter cylinder in which it moves is completely filled with fluid under pressure. However, for said emitter piston can start in the opposite direction, it is necessary to decompress said fluid contained in said cylinder. The energy loss results from the impossibility of transforming the compressive energy of said fluid into a flow rate of additional pressurized fluid available at the outlet of the receiving cylinder, except for decompressing in the same proportions the entire circuit connected to the output of said receiver cylinder. which is rarely possible.
[0003] In practice, in fact, when the emitter piston reaches the end of the stroke, the prime emitter cylinder in a low pressure circuit without labor compensation, and the energy stored compression the hydraulic fluid is dissipated in the form of nhaleur. Focusing on the application in question, this loss makes it of little concern for reducers or pressure intensifiers.
[0004] As such. it would be particularly interesting to be able to recover this energy conipr ... .. sion, particularly with regard to amplifiers or pressure reducers with pistons operating under very high pressures. For example, the reversible hydraulic pressure converter tubular valves object of patent application 1358071 of August 20, 2013 belonging to the applicant would see its energy efficiency significantly increased if it cooperated with energy recovery means of compression of the hydraulic fluid, regardless of the context of implementation of said converter. It should also be noted that, if said converter is used to make hydraulic motor vehicles with hydraulic oil storage and pressure release, recovering the compression energy of the hydraulic fluid in said converter becomes particularly advantageous and reduces the fuel consumption per kilometer of these vehicles.
[0005] The energy advantage induced by means of recovery of the compression energy of the hydraulic fluid would also benefit any converter, amplifier or sequential piston pressure reducer, regardless of the number of transmitter pistons or receiver (s) that it entails, and whatever its field of application.
[0006] It is therefore to improve the efficiency of the pressure amplifiers, pressure reducers or piston pressure converters that the end-of-stroke piston pressure regulator according to the invention proposes, according to the chosen embodiment: when the emitter piston reaches the end of the stroke, a significant fraction of the compressive energy of the hydraulic fluid in additional flow exiting the receiving cylinder, without inducing a significant drop in pressure at the outlet of the latter; simple realization and a moderate cost price Great robustness and longevity An ability to operate in the field of very high pressures, up to two thousand bars and more. The other features of the present invention have been described in the description and in the dependent claims directly or indirectly dependent on the main claim. The limit expansion valve according to the invention, provided for a piston pressure converter which comprises at least one emitter cylinder in which can move a motor-emitter piston so as to define a variable volume emitting chamber that can be placed in connection with an emitter intake duct by an emitter intake valve or with an emitter discharge duct by an emitter discharge valve, said pressure converter also comprising at least one receiving cylinder in which a pump-receiver piston can be moved so as to define a receiving chamber also of variable volume, the latter being able to transmit a hydraulic fluid coming from an inlet duct of 20 recepte: H via an inlet valve of receiving or repressing said fluid in a receiver delivery conduit via a receiver discharge valve, the emitter chamber and the receiving chamber each being filled with a hydraulic fluid. comprises at least one expansion emitter cylinder, filled with a hydraulic fluid, and in which a motor-emitter piston can be displaced so as to define a variable volume expansion emitter chamber which communicates with the emitter chamber and / or at least one expansion emitter cylinder, filled with a hydraulic fluid, and in which can move a piston 30 motor-emitter relaxation so as to define a variable volume emitter chamber that communicates with the receiving chamber; At least one expansion receiver cylinder which cooperates with the expansion emitter cylinder and in which a pump-receiver piston can be displaced so as to define with said reciprocating cylinder a variable volume expansion receiving chamber. filled with a hydraulic fluid, said pump-receiver piston being mechanically connected to the piston mr, teqr-issuer trigger by a progressive lever transmission arranged so that when the piston engine-emitter relaxation is at the top dead center , the piston pump-trigger receiver is in neutral bar. conversely, while gr-. the maximum volume of the expansion chamber is less than the maximum volume of the emitter chamber expands; - At least one trigger receiver admission valve that 'mouth in the relaxation receiver chamber and who fear--; to a hydraulic fluid contained in a receiver intake duct this detent to enter said receiving chamber but not out; - At least one expansion receiver discharge valve which opens into the expansion receiver chamber and qt ,: :-) ermet a hydraulic fluid contained in a relief receiver discharge conduit out of said receiving chamber but not d to enter it; At least one deblocking actuator can, by contact or mechanical connection, set the progressive lever transmission in motion or unblock it.
[0007] The end-of-stroke regulator according to the present invention comprises an expansion receiver inlet duct connected via H: expansion receiver ad- verse valve to the expansion receiver chamber cooperating with the variable volume expansion emitter chamber. which communicates with the receiving chamber which is connected to the receiver intake duct while the detent receiver discharge conduit connected to the same said detent receiving chamber is connected to the receiver discharge duct. Limit regulator according to the present invention comprises a conduit é .... Imission receiver receiver connected via the valve of admission of the expander to the receiving chamber holder: cooperating c the emitter chamber relaxation of variable volume which communicates with the emitter chamber which is connected to the emitter discharge duct, whereas: the expansion receiver discharge duct connected to the same said recess chamber is connected - upstream of the transmitter intake valve - to the transmitter intake duct.
[0008] The end-of-the-end regulator according to the present invention comprises a progressive toggle lever transmission which includes a return spring of the expansion pistons which tends to keep the engine-emitter piston relaxing in the vicinity of its position where the expansion emitter chamber It has the smallest volume while simultaneously, said spring allows to maintain the pump piston-receiver relaxation in the vicinity of its position where the chamber receptor relaxation has the largest y- The expander end of coi .: following the present Inition comprises a progressive-action lever transmission which consists of a crank shaft rotatable in a crankshaft bearing and having a trigger-emitting piston crank with the crank pin connected to the crank shaft. Piston pin engine-transmitter of relaxation arranged in the piston engine-emitter of relaxation by a piston rod emitter of relaxation whose first the end 15 is articulated around said crankpin and whose second evIrcs.mté about said axis, the crank shaft cooperating with secondary transmission means of relaxation which connect mechanical -ient said shaft with the pump-piston relaxation receiver 20 The det The invention relates to a second embodiment of the invention which comprises secondary detent transmission means which consist of a gear wheel for detent transmission which is integral in rotation with the crank shaft and which The rotational drive engages in linear translation of a trigger-transmission rack connected to the pump-receiver piston. The end-of-stroke regulator according to the present invention comprises secondary detent transmission means which consist of a crank arm. piston relaxation receptor integral in rotation with the crank shaft and whose crank pin is connected to a nipple of nitnn pump-receiver receiver arranged in the piston pump-iéeepteui qétei by a piston rod relaxation receiver whose first end is articulated i :-) ur said crankpin and whose second end is hinged to said axis The end-of-stroke regulator according to the present invention comprises a progressive-action lever transmission which is constituted by a camshaft rotatable in a camshaft bearing and having a detent-emitting piston cam which can be kept in contact with the engine-emitter piston and a detent reciprocating piston cam that can be held in contact with the detent pump-receiver piston. The end-of-stroke regulator according to the present invention comprises a crank shaft or a trigger-emitting piston crank or a trigger-emitting piston rod or a rebound-transmitting gear wheel or a rebound-transmitting gear rack or crank arm. piston trigger receiver or piston rod receiver trigger or camshaft or piston cam trigger or trigger piston cam follower which has a trigger-release push-button equalizes the brake release actuator relaxation can exert effort through a relaxing release pad. The following description with reference to the appended drawings, given as a non-limiting example, will make it possible to better understand the invention, the characteristics that it presents, and the advantages that it is likely to provide. Figure 1 schematically illustrates the end-of-stroke piston pressure regulator according to the present invention iii may be provided to cooperate with a piston pressure converter to a single emitter chamber and a single receiver chamber, said converter being to convert a high-pressure hydraulic fluid flow from a high-pressure fluid reservoir into a medium-pressure hydraulic fluid flow, and this, to drive a medium-pressure hydraulic motor coupled to an electricity generator . FIG. 2 schematically illustrates the end-of-travel regulator for a piston pressure converter according to the present invention, such that it can be designed to cooperate with a two-chamber emitter and two receiver-chamber piston pressure converter, said converter being implemented to convert a flow of hydraulic fluid under high pressure from a high-pressure fluid reservoir into a medium-pressure hydraulic fluid flow, and this, to drive a medium-pressure hydraulic motor coupled to a generator of electricity.
[0009] Figures 3 and 4 are schematic sections illusti i (ie operate the end of stroke pressure reducer for piston pressure converter .. according to the present invention and in a variant where the progressive lever transmission is constituted by a shaft e crank comprising a trigger-release piston crank whose crank pin eqfmli, n piston axis engine-emitter relaxation draenagé dans le piston restor-issuer relaxation by a piston rod trigger relaxation, said crank shaft cooperating with secondary triggering transmission means comprising a trigger transmission toothed wheel and an expansion gear rack Figs. 5 and 6 are schematic cross-sections illustrating the operation of the end-of-stroke pressure regulator for pistons the present invention and according to a variant in which the progressive lever transmission is of a crank shaft comprising a trigger-emitting piston crank whose crank pin is connected to a piston-engine piston-trigger axis arranged in the engine piston-expansion trigger by a relaxing trigger piston rod, said crank shaft co-operates with secondary detent transmission means, in particular constituted by a relaxation receiver piston crank sleeves the crank pin is connected to a pump-receiver piston pin of relaxation arranged in the pump-receiver piston by a piston rod relaxation receiver.
[0010] Figures 7 and 8 are schematic sections illustrating the end-of-stroke pressure-reducing valve actuator operation according to the present invention and in a variant where the progressive-effect lever transmission consists of a camshaft having a '. a trigger-emitting piston body that can be held in contact with the engine-trigger piston, and a trigger-receiving piston cam that is held in contact with the pump-receiver piston. DESCRIPTION OF THE INVENTION The end-of-stroke pressure reducing valve 1 for a piston pressure converter 2 has been shown to include at least one emitter cylinder 3 in which a piston can be moved. transmitter 7 so as to define an emitter chamber 9 of variable volume that can be put or - .ion a, emitter inlet duct 22 by a cremator intake valve 18 or with a emitter discharge 23 by a valve emitter discharge 1 said pressure converter 2 also comprising at least one receiving cylinder 4 in which can move a piston-receiver receiver 8 so as to define a receiving chamber 10 also of variable volume, the latter can admit a hydraulic fluid from a receiver intake duct 24 via a receiver inlet valve 20 or discharge said fluid into a receiver discharge duct 25 via a discharge valve of the ice-maker 2 1, the emitter chamber 9 and the receiving chamber 10 each being filled with a hydraulic fluid. FIGS. 1 and 2 show that the end-of-stroke regulator 1 according to the invention comprises at least one trigger-emitting cylinder 12, filled with a hydraulic fluid, and in which a motor-emitter piston can be displaced. 14 so as to define an expansion emitter chamber 16 of variable volume which communicates with the receiving chamber 10. As a variant not shown to replace or add to the I comprises at least one preceding cylinder the end expander transmitter transmitter trigger 12, filled with a hydraulic fluid, and in which can move a piston engine-emitter relaxation 14 so as to define a trigger chamber emitter 16 variable volume that communicates with av. Issuer 9.
[0011] It is noted that the expansion emitter chamber 16 can communicate - as the case may be - either with the emitter chamber 9 or with the receiving chamber 10 via a duct arranged in a cylinder head relaxation transmitter 44 on the emitting cylinder 12, or simply because the expansion emitter cylinder 12 opens directly into either the emitter chamber 9 or the receiving chamber 10. In the latter case, said emitter cylinder 12 does not have an expansion emitter cylinder head 44 and can respectively lead to the inner surface of a cylinder head issuer 5 capping the transmitter cylinder 3 or at the inner surface of a receiver cylinder head 6 capping the receiver cylinder 4. 0 Note also in the figures 1 to 8 that the end regulator runs. according to the invention comprises at least one cylinder, detent receiver 1 cooperates with the expansion emitter cylinder 12 and L.nns which can move a pump piston-trigger receiver 15 so as to define with said receiver cylinder 13 a chamber Variable volume expansion receiver 17 filled with a hydraulic fluid, said pump-receiver piston 15 being mechanically connected to the expansion motor-emitter piston 14 by a progressive-action lever transmission 11 arranged in such a way that when the piston-motor trigger transmitter 14 is at top dead center, the pump piston-trigger piston 15 is at the bottom dead center and vice versa, while the maximum volume of the expansion receiver chamber 17 is less than the maximum volume of the expansion emitter chamber 16 It should be noted that the progressive lever transmission 11 defines between the engine piston-expansion piston 14 and the pump piston-receiver relaxation 15 n Rappo such transmission, that when said engine-emitter piston 14 is placed in its top dead center and therefore the volume of the expansion emitter chamber 16 is minimal, said engine-emitter piston 14 can not - despite the pressure of the fluid the hydraulic pump to which it is exposed - to move and thereby drive the p; sLe pump-trigger receiver 15, while plus the piston engine-emitter relaxation 14 is removed from said top dead center, plus the effort it is capable of transmitting to the piston pump-trigger receiver 15 is important, as well as its ability to move said pump-receiver piston 15. It is further noted that the piston engine-emitter relaxation 14 and / or the niston-pump Expansion receptor 15 may comprise at least one seal 1, at least one seal segment. FIGS. 1 to 8 show that the detent L: end of stroke 1 according to the invention comprises at least one detent receiver 26 which opens into the expansion receiver chamber 17 and which allows a hydraulic fluid contained in a detent receiver admission duct 28 to enter said receiving chamber 17 but not to exit. FIGS. 1 to 8 also show that the end-of-stroke expander comprises at least one expansion receiver discharge valve 27 which opens into the expansion receiving chamber 17 and which: let to a hydraulic fluid contained in a receiver discharge pipe to relax out of said receiving chamber 1 7 but not to enter. Moreover, it is noted that the expansion receiver intake valve 26 and / or the expansion receiver discharge valve 27 can be arranged in a receiver cylinder head: e trigger 45 which closes one end of the receiver cylinder of 13 or in the closed end of said cylinder 13 if it is blind.
[0012] It will be noted in FIGS. 1 to 8 that the end-of-stroke regulator 1 according to the invention also comprises at least one trigger release actuator 30 that can, by contact or mechanical link, set the lever-action lever transmission 11 in motion or unblock this last so as to set in motion the piston motor-emitter relaxation 14 and the pump piston-receiver relaxation 15 when the piston r Jr-emitter relaxation 14 is placed in its top dead center or in the vicinity ue ue last, and this for example to achieve a transmission ratio between said pistons 14, 15 sufficient for the piston engine-expansion 14 can continue to run without the aid of the trigger release actuator 30.
[0013] It should be noted that the trigger release actuator 30 can be hydraulic, electro-hydraulic, electric, pneumatic, or generally, of any type known to those skilled in the art. In addition, the trigger release actuator 30 can be controlled by a pressure regulator 55 which manages or co-operates with the operation of the piston pressure converter 2. As illustrated in FIGS. 1 and 2, the expansion receiver admission duct 28 connected via the expansion receiver intake valve 26 to the expansion receiver chamber 17 cooperating with the variable volume expansion chamber 16 which communicates with the receiving chamber 10 can be connected to the receiver intake duct 24 while the expansion receiver discharge duct 29 connected to the same said expansion receiver chamber 17 can be connected to the discharge duct e: a receiver 25 In a configuration not illustrated by the figures , the trigger receiver admission duct 28 connected via the trigger receiver admission valve to the trigger receiver chamber 17 cooperating with the expansion emitter chamber 16 of variable volume which communicates with the emitter chamber 9 can be connected to the emitter discharge conduit 23 while the expansion receiver discharge conduit 29 connected to the same said expansion receiver chamber 17 can be connected - upstream of the emitter intake valve 18 - to the emitter intake duct 22. In FIGS. 3 to 8, it can be seen that the progressive-effect lever transmission 11 may comprise a return spring expansion pistons 33 which tends to maintain the engine-emitter piston relaxation 14 in the vicinity of its position where the expansion emitter chamber 16 has the smallest volume while simultaneously, said spring 33 can maintain IE, eiston pump-receiver expansion in the vicinity of its position where the expansion receiving chamber 17 has the largest volume, said spring 33 being able to be torsion, flexion, traction or compression e t be of any type known to those skilled in the art. FIGS. 3 to 6 show that according to the end-of-course regulator according to the invention, the progressive-lever lever transmission 11 may consist of a crankshaft 46, which may be 1 in a shaft bearing to crank 47 and having a trigger-emitting pin crank 35 whose crank pin 48 is connected to an engine-emitter piston axis 49 of relaxation arranged in the engine-emitter piston relaxation 14 by a piston rod relaxation transmitter 34 whose first end is articulated around said crank pin 48 and whose second end is articulated around said axis 49, the crank shaft 46 cooperating with secondary expansion means of transmission 51 which mechanically connect said shaft 46 with the pump-receiver piston 15. FIGS. 3 and 4 show that the secondary drive means of detent 51 can be made up of a drive gear 34 i is solid, in rotation with the crankshaft 46 and which, when rotated, drives in linear translation an expansion transmission rack 37 connected to the pump-receiver piston 15 directly or via a leg It is noted that the push-thrust rack 37 can be guided, in particular by at least one rack-and-pinion guide wheel 38.
[0014] According to the particular configuration shown in FIGS. 5 and 6, the secondary triggering transmission means 51 can be fitted with a relaxation receiver piston crank 40 integral in rotation with the crank shaft 46 and whose crank pin 48 is connected to a piston-pin recoil-receiver-receiver 50 arranged in the pump piston-receiver relaxation 15 by a piston rod relaxation receiver 41 whose first end is articulated around said crankpin 48 and whose second end is articulated about said axis 50. It is easily conceivable that, according to a variant not shown, the secondary transmission means tent 51 may also consist of a cam integral rotationally rbre crank 46 and can be maintained in contact with the piston 15. As an alternative embodiment shown in FIGS. 7 and 8, the invention relates to: 3 progressive effect 11 may consist of a shaft carnes 52 being rotatable in a crankshaft bearing 53 and having a detent-emitting piston cam 42 which can be held in contact with the expansion-engine piston-emitter 14 and an expansion-receiver piston cam 43 (-. , in order to keep it in contact with the piston pump-expansion receiver 15. As an alternative, not shown, the relaxation receiver piston cam 43 may be replaced by a crank integral in rotation with the crank shaft 52, said crank comprising a crankpin connected to an axis arranged in the piston pump-recess receiver 15 by a connecting rod whose first end is articulated around said crankpin and whose second end is articulated about said axis. It is noted that the crankshaft 46 or the trigger-emitting piston crank 30 or the connecting rod 34 or the trigger transmission gear 36 or the trigger transmission rack 34 37 or the trigger recess piston crank 40 or the expansion receiver piston rod 41 or the camshaft 52 or the trigger emitter piston car 42 or the detent receiver piston cam 13 may have a thrust stopper releasing means 32 for which the trigger release actuator 30 can exert a force via a trigger release button 31 to move the piston motor-emitter 14 and the piston pump-trigger receiver 15 when, -pisioillnoteur-issuer trigger 14 is placed in its top dead center or in the vicinity of the latter. It will be noted that FIGS. 1 to 8 are a variant in which the unlocking push-button 32 is provided on the trigger-emitting piston level. OPERATION OF THE INVENTION the foregoing description and in connection with Figures 1 to 8, the operation of the end-of-stroke regulator 1 for a hydraulic pressure converter 2 according to the present invention is understood. It was chosen here to illustrate the operation of said regulator 1 using the latter 15 to recover the compression energy of a hydraulic fluid used in a piston pressure converter 2 used as a pressure reducer of which two configurations are schematically For simplicity, we will consider mainly the diagram of Figure 1 which exposes a pressure converter e -istons 2 to a single emitter chamber 9 and a single receiving chamber 10. The application that illustrates FIG. 1 is intended to convert stored energy in the form of compressed nitrogen into a high-pressure fluid reservoir 58 into electricity by means of an electricity generator 62 driven by a medium-pressure hydraulic motor 59 The compressed nitrogen communicates its pressure to a hydraulic fluid that can circulate in the ducts 64 in particular. wedged between the high pressure fluid reservoir 58 and the medium pressure hydraulic motor 59 a piston pressure converter 2 which converts a high-pressure flow rate of hydraulic fluid exiting said reservoir 58 into a medium-pressure flow rate of hydraulic fluid, the latter entering the medium-pressure hydraulic motor 59 via an inlet duct of the hydraulic motor 60. To filter the pulsations generated by the operation of the piston pressure converter 2, it will be noted that the engine inlet duct According to this example, the hydraulic system 60 comprises a medium-pressure fluid reservoir 57.
[0015] FIG. 1 shows that in order to generate a medium-pressure flow rate of hydraulic fluid entering the medium-pressure hydraulic motor 59, the high-pressure fluid reservoir 58 must be communicated with the emitter chamber 9. the pressure converter management computer 55 opens the emitter intake valve 18 which allows the hydraulic fluid contained in the pressure medium tank 58 to enter the emitter chamber 9 via the air duct. However, said calculator simultaneously prevents said fluid from leaving said chamber 9 to go to the emitter outlet low-pressure fluid reservoir 56, said calculator 55 maintaining for this the discharge valve of Thus, the high pressure hydraulic fluid from said tank 58 can push on the engine-emitter piston 7, which moves in the direction d2, which has the effect of placing the receiver-pump piston 8 in the same direction over the same distance and at the same speed.
[0016] Moving in the direction d2, the pump-receiver piston 8 compresses the hydraulic fluid contained in the receiving chamber 10, which has the effect of expelling said fluid in the receiver discharge pipe 25 via the receiver discharge valve 21. Said fluid is then conveyed via a conduit 64 to the inlet duct of the hydraulic motor 60 which has the effect of rotating the medium-pressure hydraulic motor 59 and Tluent. the electricity generator 62, which produces electricity. The position sensor of the pressure converter pistons 54 continuously returns the position of the pump-receiver piston 8 to the control computer of the pressure converter 55. When the pump-receiver piston 8 comes close to the receiver cylinder head 6, said computer 55 closes the emitter admission valve 18 so as to stop the displacement of the pump-receiver piston 8 in the direction d2 before it touches said cylinder head and so that said piston 8 remains at a certain distance from said cylinder head Before the engine-emitter piston 7 and the pump-receiver piston 8 can not start in the opposite direction in the dl direction, it is advantageous to decompress the emitting chamber 9. If we leave it to what allows the state of the art and technique, the management computer of the pressure converter 55 should at this stage open the emitter discharge valve 19 to decompress said chamber 9 in the low-p fluid reservoir transmitter output ression 56, which would have the effect of dissipating the compression energy of the hydraulic fluid contained in the emitter chamber 9, said energy can definitely no longer be converted into additional flow of hydraulic fluid leaving the discharge pipe of receiver 25.
[0017] It is to avoid this energy loss that at this stage, the end-of-stroke pressure regulator 1 for a piston pressure converter 2 according to the present invention provides that the control computer of the pressure converter 55 does not open the valve yet. emitter discharge 19 so that said expander 1 can produce its effects and recover the compression energy of the hydraulic fluid contained in the emitter chamber 9. For this, immediately after closing the emitter admission valve 18, the control computer of the pressure converter f supplies the trigger release actuator 30 with electrical current, which makes it possible to set in motion the progressive-lever transmission 11 and consequently to set the piston engine in motion trigger-emitter 14 and the piston pump-trigger receiver 15, the piston engine-emitter relaxation 14 being hitherto eionné in its top dead center For details In the operation of the end-of-stroke regulator 1 according to the invention, the embodiment of the progressive-action lever transmission 11 which is shown in FIGS. 3 and 4 has been chosen here.
[0018] FIG. 3 shows the state in which the end-of-stroke regulator 1 according to the invention was located as long as the engine-emitter piston 7 and the pump-receiver piston 8 were moving in the direction d2. It should be noted that the engine-emitter piston 14 remains stuck in its top dead center because the pressure that the hydraulic fluid contained in receiving amber 10 exerted on said piston 14 tended to turn the crank shaft 46 in the opposite direction of the needles. of a watch. That the piston motor-emitter relaxation 14 remains blocked is due to the fact that - according to this particular embodiment illustrated in Figure 3 and 4 - when said piston 14 is parked at its top dead center, the axis of rotation of the rn9neton of 48 is substantially misaligned with respect to the portion which connects the axis of rotation of the piston-emitter piston shaft 49 and the axis of rotation of the crank shaft 46, while the center of rotation of the piston-emitter piston axis relaxation 49 and the axis of the trigger cylinder 12 are perpendicular and intersecting, and that is the same for the axis of rotation of the crank shaft 46 and said axis of said cylinder 12. It is noted - still in Figure 3 - that it was also impossible for the motor-emitter piston the trigger 14 to rotate the crank shaft 46 more counterclockwise as the thrust unlocking push-button 32 that features the trigger-emitting piston crank 35 abutted on the trigger release button 31, the latter being held in the stationary position by the trigger release actuator 30.
[0019] It is also noted - in addition to what is exposed - that the return spring of the expansion pistons 33 tends to turn the crank shaft 46 counterclockwise and therefore, at maintain the push-release release push-button 32 in contact with the trigger release button 31 It is understood from FIGS. 3 and 4 that as soon as the control computer of the pressure converter 55 supplies the trigger release actuator 30 with electrical current, said actuator 30 pushes the trigger release button 31 which, by pushing in turn on the trigger release push-button 32 that includes the trigger-emitting piston gear 35, rotates the crank shaft 46 a few degrees clockwise so as to shift the misalignment of the axis of rotation of the crank pin 48 from below to above the straight line which connects the axis of rotation of the crank the piston axis moteu This results from the fact that the thrust produced by the engine piston-emitter 14 under the effect of the pressure of the hydraulic fluid contained in the receiving chamber 10 - said pressure being echoed to the triggering emitter chamber 16 these two said communicating chambers 10 and 16 now tends to turn the crankshaft 46 in the direction of clockwise, which becomes possible because only the piston-recess piston 15 and the return spring of the expansion pistons 33 now tend to oppose this rotation without being able to prevent it.
[0020] Recall that the transmitter inlet valve 18 and the emitter discharge valve 19 are both closed, the engine-emitter piston 7 and the pump-receiver piston 8 are temporarily stopped. Correlatively, as long as the engine piston / expansion piston 14 is in the vicinity of its dead point hau pressure prevailing in the emitter chamber 9 approximately corresponds to the pressure in the high pressure fluid reservoir 58 while the pressure prevailing in the cjre The receiver 10 is equivalent to the pressure previously prevailing in the inlet cone of the hydraulic motor 60. It is at this stage that the role of the end-of-stroke regulator 1 for a piston pressure converter 2 following the The present invention becomes determinative since said expander 1 will decompress the emitter chamber 9 and the receiving chamber 10 and use this decompression to generate an additional hydraulic fluid flow rate available at the inlet duct of the hydraulic motor 60, the pressure of said fluid being substantially equivalent to that which it in said conduit 60 k .lue the piston engine-transmitter 7 and the piston pump-récepts ur 8 moved, but here in the sense d2. It will be noted in FIGS. 3 and 4 that the engine-emitter piston 14 exposes the pressure of the hydraulic fluid to a section much greater than that exhibited by the pump-receiver piston 15 which is noticed - again in the same figures - as the transmission ratio e the piston engine-emitter relaxation 14 and the pump piston-receiver relaxation is large or even infinitely large when said piston engine-emitter 14 is pla.cé on or near its top dead center. and small when said engine-emitter piston 14 is positioned at the point mor. i_> ace. It is also noted that advantageously, the complete travel of the engine piston-emitter relaxation 14 operates only a quarter turn of the crank shaft 4 This decreasing transmission ratio comes - first - from the system that constitute the trigger-emitting piston rod 34 and the trigger-emitting piston crank 35, said system offering a short or even infinitely short arm to the engine-emitter piston 14 for rotating: - ,. the crank shaft 46 when said piston 14 is on or near its top dead center, said lever arm becoming maximum when said piston 14 is in its bottom dead center. This decisive transmission ratio derives - secondly - because unlike the piston motor-emitter relaxation 14, the drive in linear translation of the piston pump-trigger receiver 15 by the crank shaft 46 operates with constant leverage since the secondary triggering transmission means 51 in question are constituted - according to this nonlimiting exemplary embodiment - of a trigger transmission toothed wheel 36 driving an expansion transmission rack 37.
[0021] The difference in section and the variable transmission ratio between the engine-emitter piston 14 and relaxation piston-receiver piston 15 can relax the hydraulic fluid contained in the emitter chamber 9 and the receiving chamber 10 in the desired conditions c That is, using this trigger to generate an additional medium hydraulic fluid flow at the inlet duct of the hydraulic motor 60. At the beginning of the expansion - that is, when the piston engine-issuer relaxation 14 is in the vicinity of its top dead center - the pressure in the receiving chamber 10 is substantially equal to the desired pressure at the inlet duct of the hydraulic motor 60. The effort exerted by the pressure prevailing in the receiving chamber 10 on the engine piston-emitter 14 is - for example - ten times greater than that to be exerted on the piston pump-receiver the instantaneous transmission ratio between the piston engine-emitter relaxation 14 and the pump piston-receiver relaxation 15 is - for example - of a sur & ç. In this case, the pump piston-receiver relaxation 15 pressurizes the chamber, which :, receives relaxation with which it cooperates with the desired pressure, site it begins to expel from said receiving chamber 17 the hydraulic fluid that it contains in the expansion receiver discharge duct 29 via the expansion receiver discharge valve 27.
[0022] At this stage, your motor-emitter 7 and the pump-receiver piston 8 begin to substantially in the direction d2 under the effect of the expansion of the emitting chamber: 9. As the chamber relaxes 9, the piston engine-emitter relaxation 14 moves towards its bottom dead center while decreases the pressure it receives from the hydraulic fluid from the receiving chamber 10. In doing so, the transmission ratio between said piston 14 and the pump piston-recess receiver 15 increases to reach approximately one when the piston engine-emitter relaxation 14 reaches its bottom dead point, Thus, while the pressure prevailing in e-chamber-detector 9 and the receiving chamber 10 fell the pressure of the hydraulic fluid expelled from the expansion receiver chamber 17 by the pump-receiver piston 15 via the expansion receiver discharge valve 27 remained relatively constant. As the flow rate entering the hydraulic medium-pressure motor 59 has remained constant during this sequence, the crankshaft rotation speed 46 t has been increased correspondingly to the decompression of the emitter 9 and receiver 10 chambers, said decompression having also caused a displacement in the direction d2 and a short distance from the engine-emitter piston 7 and the pump-receiver piston 8.
[0023] Once the emitting chamber 9 and the receiving chamber 10 have been decompressed, the management computer of the pressure converter 55 can open the emitter discharge valve 19. As a result, the engine-emitter piston 7 and the pump-receiver piston 8 move rapidly in the direction dl under the effect of the pressure exerted by the hydraulic fluid., held in the receiver low-pressure fluid reservoir 63 over the entire section at the pump-receiver piston 8, via the receiver intake valve 20. When the engine-emitter piston 7 arrives near the cylinder cylinder head 5 transmitter, the olecule. ::, management of the pressure converter 55 closes the emitter discharge valve 19 and the engine-emitter piston 7 and the pump-receiver piston 8 stop moving in the direction dl. In doing so, the return spring of the expansion pistons 3 brings the engine-emitter piston 14 to the top dead center, and brings back the push-release trigger stop 32 in contact with the trigger release button 31.
[0024] At the same time, the expansion pump-receiver piston 15 returns to its low dead point by sucking - via the expansion receiver intake valve 26 - hydraulic fluid from the receiver low-pressure fluid reservoir 63 so that filling the relaxation receiving chamber 17.
[0025] Thus, the engine-emitter piston 7 and the pump-receiver piston 8 of the piston pressure converter 2 are ready to make a new stroke in the direction d2 to convert the high-pressure flow of hydraulic fluid leaving the high fluid reservoir. pressure 58 at a medium-pressure flow rate of hydraulic fluid entering the medium-pressure hydraulic motor 59 before exiting via the outlet duct of the hydraulic motor 61 for Halernent to open into a hydraulic fluid tank 65. In addition, the end of cc expansion valve 1 according to the invention E louveau pre-decompress the emitter chamber 9 and recover the energy of ompression of the hydraulic fluid contained in said chamber 9 when the pump-receiver piston 8 will arrive again near the (: It is easy to understand the related operation of the variants of the end-of-stroke regulator 1 for a piston pressure converter 2 according to the invention. 3. As is readily apparent from the application of said regulator 1, whether it is the one shown in FIG. 2, or any other, without limitation, whether or not it is applied; eonvertissé! pressure or any other known machine or .1) r1 of those skilled in the art and found with the end-of-stroke valve 1 salt - the invention an olution recovery compression energy contained in any gaseous liquid fluid.
[0026] It should be understood that the foregoing description has been given only by way of example and which in no way limits the scope of the invention: it can not be dispensed with by replacing the details of execution described by any other equivalent.

权利要求:
Claims (3)
[0001]
REVENDICATIONS1. Limit regulator (1) provided for a piston pressure converter (2) which comprises at least one emitter cylinder (3) in which a motor-emitter piston (7) can move in order to define an emitter chamber ( 9) of variable volume which can be fed with an emitter intake duct (22) by an emitter intake valve (18) or with an emitter discharge duct (23) by a valve transmitter (19), said pressure converter (2) also comprising at least one receiver cylinder (4) in which a pump-receiver piston (8) can move so as to define a receiving chamber (10) as well of variable volume, the latter being able to admit a hydraulic fluid coming from a receiver intake duct (24) via a valve of the receiver Amission (20) or to repress said fluid in a receiver inle conduit (25) via u .. ',.: receiver discharge fart (21), the ut amber emitting (9) and the receiving chamber (10) each being filled with a hydraulic fluid, characterized in that it comprises - At least one relaxation emitter cylinder (12), filled with a hydraulic fluid, and wherein can move an engine-emitter piston relaxation (14) so as to define a trigger chamber (16) of variable volume that communicates with the emitter chamber (9) and / or at least one trigger emitter cylinder (12) , filled with a hydraulic fluid, and (equel can move a piston engine-emitter relaxation (14) of. ', Le to define a trigger emitter chamber (16) of variable volume which communicates with the receiving chamber (10). ); At least one expansion receiving cylinder (13) which cooperates with the expansion emitter cylinder (12) and in which a pump-receiver piston (15) can be displaced so as to define with said receiver cylinder (3) a chamber a variable-volume expansion receiver (17) filled with a hydraulic fluid, said pump-receiver piston (15) being mechanically connected to the engine-emitter piston (14) by means of a progressive-action lever transmission (11) arranged such that when the engine-emitter piston (14) is in the top dead center, the pump-receiver piston (15) is in bottom dead center inversely; At least one expansion receiver inlet valve (26) which opens into the expansion receiver chamber (17) Pt which allows a hydraulic fluid contained in an expansion receiver inlet (28). to enter but not exit from said receiving chamber 17. At least one expansion receiver discharge valve (27) which opens into the expansion receiving chamber (17) and which allows a hydraulic fluid contained in a conduit pressure relief device (29 :: '- .ortir said receiving chamber (17) but not to enter therein; at least one trigger release actuator k30) being able to contact or mechanical connection by setting the transmission in motion with progressive effect lever (11) or unlock the latter.
[0002]
2. Limit regulator (1) according to claim 1; characterized in that the expansion receiver intake duct (28) connected via the expansion receiver inlet valve (26) to the combustion chamber (7) cooperating with the expansion emitter chamber a variable which communicates with the receiving chamber (10) at the receiver intake duct (24) while the detent receiver discharge duct (29) is connected to the same said detent receiving chamber 25 (17) is connected to the recovery delivery pipe. '23).
[0003]
3, end-of-stroke regulator (1) according to claim 1, characterized in that the expansion receiver intake duct (28) connected via the intake valve recer, .. eur relaxation (26) to the expansion receiving chamber 30 (17) co-operating with id expansion emitting chamber (16) of volum e -vancble which communicates with the emitting chamber r9) is connected to the emitter discharge conduit (23) while the discharge conduit an expansion receiver (29) connected to the same said relaxation chamber (17) is connected upstream of the transmitter intake (18) to the transmitter intake duct (24). Limit regulator (1) according to Claim 1, characterized in that the progressive-action lever transmission (11) comprises a return spring for the expansion pistons (33) which tends to hold the engine-emitter piston of detent (14) in the vicinity of its position where the expansion emitting chamber (16) presents the smallest volume while simultaneously, said spring (33) allows to maintain the pump-receiver piston relaxation (15) in the vicinity of its position where the expansion receiver chamber (17) has the largest volume. 5. Limit switch (1) according to claim 1, characterized in that the progressive lever transmission (1-1) consists of a crank shaft (46) rotatable in a shaft bearing. crank (47) and having a trigger-emitting piston crank (35) whose crank pin (48) is connected to an engine-emitter piston shaft (49) arranged in the engine-emitter piston. ; (14) by a trigger-emitting piston rod (34) whose first end is articulated around said crankpin (48) and whose second end is arranged around said axle (49), the crankshaft ( 46) cooperating with secondary detent transmission means (51) which mechanically connect said shaft (46) with the pump-receiver piston (15). 6, end-of-stroke regulator (1) according to claim 5, characterized in that the secondary transmission means of relaxation 1) consist of a wheel ce; P. of the trigger transmission (36) which is integral in rotation with the crank shaft (46) and which, when it is rotating, drives in translation linear a trigger transmission rack (37) connected to the pump piston-receiver piston (15). 7. End-of-stroke expansion valve (1) according to claim 5, characterized in that the secondary expansion means (bj consist of a piston piston relaxation receiver (40) integral in rotation with the shaft to crank (46) and the crank pin (48) of which is connected to a pump-receiver piston pin (50) arranged in the pump-receiver piston (15) by means of a trigger-reducing piston rod (41). ) whose first end is articulated around said crankpin (48) and whose second end is hinged about said axis (50) .8, end-of-stroke regulator (1) according to claim 1, characterized in that the lever transmission with progressive effect (11) consists of a camshaft (52) rotatable in a camshaft bearing (53) having a detent-emitting piston cam (42) which can be held in contact with the engine piston. trigger transmitter (14) and the cam detent recess piston (43) which can be held in contact with the pump-receiver piston (15). 9. Expansion valve (1) according to any one of claims 5 to 8, characterized in that the crank shaft (46) or the piston piston relaxation transmitter (35) or the piston rod transmitter expansion gear (34) 01 trigger gear (36) or trigger transmission rack (37) or hold receiver piston handle (40) or trigger receiver piston rod (41) or the camshaft (52) or the detent-emitting piston cam (42) or the detent-recess piston cam (43) has a detent-releasing push-button ( , 2) on which the disengagement actuator trigger (30) can exert a force through a trigger release button (31).

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同族专利:

公开号 | 公开日

AU2015261366B2|2018-08-23|

ES2709397T3|2019-04-16|

CA2946466A1|2015-11-19|

JP2017520725A|2017-07-27|

FR3020840B1|2017-03-03|

FR3020840A1|2015-11-13|

WO2015173495A1|2015-11-19|

KR20170002430A|2017-01-06|

CN106662082B|2018-12-28|

KR102277604B1|2021-07-14|

EP3143288A1|2017-03-22|

CN106662082A|2017-05-10|

FR3020841B1|2017-07-07|

JP6559704B2|2019-08-14|

US9856891B2|2018-01-02|

US20150322976A1|2015-11-12|

AU2015261366A1|2016-12-15|

EP3143288B1|2018-11-07|

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法律状态:
2015-06-18| PLFP| Fee payment|Year of fee payment: 2 |

2015-11-13| PLSC| Search report ready|Effective date: 20151113 |

2016-06-28| PLFP| Fee payment|Year of fee payment: 3 |

2017-06-27| PLFP| Fee payment|Year of fee payment: 4 |

2018-06-26| PLFP| Fee payment|Year of fee payment: 5 |

2020-06-25| PLFP| Fee payment|Year of fee payment: 7 |

2021-06-25| PLFP| Fee payment|Year of fee payment: 8 |

优先权:

申请号 | 申请日 | 专利标题

FR1454223A|FR3020840B1|2014-05-12|2014-05-12|LIMIT SWITCH FOR PISTON PRESSURE CONVERTER|

FR1455710A|FR3020841B1|2014-05-12|2014-06-20|END LIMIT HOLDER FOR PISTON PRESSURE CONVERTER|FR1455710A| FR3020841B1|2014-05-12|2014-06-20|END LIMIT HOLDER FOR PISTON PRESSURE CONVERTER|

CN201580024795.2A| CN106662082B|2014-05-12|2015-05-07|End of travel expansion valve for piston-type pressure converter|

JP2016563464A| JP6559704B2|2014-05-12|2015-05-07|End stroke expansion machine for piston pressure conversion|

AU2015261366A| AU2015261366B2|2014-05-12|2015-05-07|End-of-stroke expander for piston-type pressure converter|

CA2946466A| CA2946466A1|2014-05-12|2015-05-07|End-of-stroke expander for piston-type pressure converter|

KR1020167031252A| KR102277604B1|2014-05-12|2015-05-07|End-of-stroke expander for piston-type pressure converter|

EP15732299.1A| EP3143288B1|2014-05-12|2015-05-07|Pressure converter with pistons comprising end-of-stroke pressure reducer|

PCT/FR2015/051209| WO2015173495A1|2014-05-12|2015-05-07|End-of-stroke expander for piston-type pressure converter|

ES15732299T| ES2709397T3|2014-05-12|2015-05-07|Pressure converter with piston comprising an end-of-travel pressure reducer|

US14/709,036| US9856891B2|2014-05-12|2015-05-11|Travel end expansion valve for piston type pressure converter|

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