FR2588045A1 - Drive machine with pressurised compressible fluid or liquid - Google Patents

Abstract

The invention relates to a drive machine with pressurised compressible liquid or fluid. It will find an application in the field of driving any mechanical device. The drive machine 1 comprises a sealed vessel 3 in which a valve device 9 creates a reciprocating motion. This device 9 consists of a piston 10 mounted so that it slides in a sealed fashion in the vessel 3, dividing it into two working chambers, one called the first intake chamber 12, the other called the second intake chamber 13. According to the invention, the drive machine 1 comprises: - means for communicating able between the two working chambers provided in the piston 10, to connect the said first and second chambers 12, 13 so they can cooperate with each other; - means for temporarily and sequentially obstructing the said communicating and which can be controlled by the pressure of a liquid and/or a compressible fluid to obstruct the communication means so as to allow a first intake displacing the piston 10 in the "go" direction, and then to unobstruct the communicating means so as to put the chambers into communication to allow a second intake displacing the piston 10 in the "return" direction.

Description

 The invention relates to a liquid or compressible fluid driving machine. It can be used for the drive of any mechanical device driven by an alternating movement such as in particular the drive of suction pumps or even explosion-proof pumps for transferring more or less viscous liquids.

 In fact, in many fields, pumps are used which allow the evacuation or transfer of more or less viscous liquids. These pumps are generally actuated by motive machines which use as energy either compressed air, athermal energy, or even electrical energy.

 More particularly when they are used in environments where there is a risk of explosion, they are built according to strict rules to prevent them from producing during heating or sparks which are liable to create an explosion. They are then constructed with a so-called explosion-proof construction.

 To avoid the complications of construction of such explosion-proof mactins, very often, the energy used is limited to compressed air and thus all the problems of sparks created by thermal energy or electrical energy are avoided.

 There are known re ai isati ons of ira chines driven actuated by compressed air which are constituted by a sealed enclosure in which slides a piston actuated by compressed air and capable of delivering a reciprocating movement. This reciprocating movement is then transmitted by an output shaft to a pump which allows in particular the transfer of liquids.

 Such ruptures are also known to those skilled in the art and are generally constituted by a device which sucks the liquid during the forward movement of the reciprocating motor and discharges this liquid during its return movement.

 nien that giving satisfaction to some of their users, such devices nevertheless have two major disadvantages ellr s; indeed, it is essential to have a compressed air distribution network to operate the driving machine on the one hand, and on the other hand such machines driven by rhymed air camp give rise to a significant noise which causes nuisance in its close environment.

 Furthermore, to produce the drive piston of the driving machine, and more precisely the valve device which allows it to reciprocate, we use to achieve the sealing of the orifices this communication authorizing the operation of the valve of the plastic seals including rubber.

 However, in certain fields of use, in particular in the food or cosmetic industry, it is important to avoid the accumulation of bacteria in the machines used. Therefore, this requires the use of very high quality synthetic seals whose cost is high. In addition, these seals have premature wear due to frequent cleaning with specific disinfectants which more or less disintegrate the material.

 The object of the present invention is to provide an i-liquid or compressible fluid driving machine, in particular used for driving explosion-proof pumps for transferring more or less viscous liquids, which uses as compressible energy a compressible fluid such as in particular of compressed air or a liquid such as in particular pressurized water. Thus with the machine of the present invention it is no longer essential to have a compressed air distribution network, this machine being able to connect to a traditional water supply network.

 Another object of the present invention is to provide a liquid or fluid compressible pressurized power machine which, by virtue of its construction, minimizes the use of expensive and unreliable plastic seals as much as possible.

 Another object of the present invention is to provide a liquid or fluid compressible pressurized power machine which, by virtue of its construction, allows it to be completely dismantled easily to allow frequent cleaning as required in the food or cosmetic industry.

 Another object of the present invention is to provide a liquid or compressible fluid pressurized power machine which can reduce the nuisance caused by the noise generated by its operation.

 Other objects and advantages of the present invention will appear during the description which follows which is however given only for information and has not been intended to limit it.

According to the present invention, the drive machine for liquid or fluid compressible under pressure in particular used for driving anti-deflagration pumps for transferring more or less viscous liquids, comprising a sealed enclosure having an intake area and a delivery, and in which a valve device creates a reciprocating movement, the said valve device comprises a piston, integral with an output shaft, mounted with leaktight sliding in said enclosure, dividing it into two working chambers, the one said first admission chamber, the other said second admission chamber, is characterized in that it comprises
communication means of the two working chambers, placed at the level of said piston, capable of connecting said first and second intake chambers so that they can cooperate together, and,
- temporary sequential sealing means of said means of communication, able to be controlled by the pressure of a liquid and / or a compressible fluid whose flow circulates in said enclosure from the intake zone to the zone exhaust, to close the communication means of the two chambers, to authorize a first admission moving the piston in the "go" direction then to unblock the communication means of the two chambers in order to put them in communication to authorize a second inlet moving the piston backward. "

 The present invention will be better understood on reading the description which follows, accompanied by the attached drawings, which form an integral part thereof.

 Figure I represents a motor machine with liquid or fluid compressible under pressure produced according to the present invention and applied to the drive of an explosion-proof pump for transferring liquids.

 2 shows a sectional view of the drive machine shown in Figure I in an operating state.

 Figure 3 shows in section the engine shown in Figure I in another operating state.

 The present invention relates to a liquid or fluid compressible pressurized rnotatrice machine which allows to drive in a alternating movement any mechanical device not requiring.

 More particularly in the context of the present description, it will be applied to the driving of a pump for transferring more or less viscous liquids. Furthermore, it should be noted that the present machine could be applied to other types of pumps.

 Generally in specific fields such as in the food industry or the cosmetics industry or even explosive risk environments such as in particular in mines or in painting installations, it is advantageous to use machines which are of a simple design, easily detachable, and not causing heating or sparks capable of creating the explosion.

 This is why it is commonly used motor nachines supplied with energy by a compressible fluid under pressure such as in particular compressed air.

However, this requires the presence of compressed air at the place where the machine is to be used, which is not always the case.

 One of the aims of the present invention will make it possible to overcome this drawback by authorizing the operation of the same matrix machine either by means of a liquid under pressure or by means of a compressible fluid under pressure.

 In fact, the driving machine of the present invention may in particular be connected to a conventional pneumatic distribution network whose pressure can commonly range up to six bars. But it can also without adaptation connect to a water distribution network whose pressure can be between one and ten bars.

 Figure I shows a sectional view of the drive machine (I) of the present invention used in combination with a pump (2) for transferring more or less viscous liquids. The assembly then realizes an explosion-proof motorcycle pump assembly.

 More specifically, the drive machine (I) for liquid or fluid compressible under pressure essentially comprises a sealed enclosure (3) which has an inlet zone (4) and a discharge zone (5) of the liquid or compressible fluid used as driving energy.

 For example, the enclosure (3) may consist of a cylinder (fi) whose two lateral faces (7 and B) are closed by suitable flanges, the sealing between the flanges and the cylinder being in particular produced by seals traditional according to techniques known to those skilled in the art.

In particular, in the case of the food or cosmetic industry, qualities of seals will be used which facilitate cleaning to avoid hacteria, they will preferably be chosen from the ertalon family.

 In the preferred embodiment shown in Figure I the side flanges (7 and 8) will be fixed to the cylinder (6) noting by screwing thus ensuring slight compression of said seals.

 In this reed enclosure (3) is arranged a valve device (9) capable of creating an alternating movement.

To this end, the device (9) comprises a piston (In) which is made integral with an output shaft (-îî). This assembly is mounted with sealed sliding in said enclosure (3).

Therefore, the enclosure (3) is divided into two working chambers, one called the first admission chamber (I2), the other called the second admission chamber (13). Thus, by this arrangement, the piston (IO) will authorize a reciprocating "round trip
This movement will be more particularly described with reference to FIGS. 2 and 3 which: respectively show the stages of operation of the motor machine (I) of the present invention. More particularly, FIG. 2 shows the valve device (9) in a state such that it authorizes the movement of the piston in the "go" direction, on the other hand, FIG. 3 shows it in the other state allowing the direction " back ". On these two figures we see represented more precisely the constitution of the sealed enclosure (3) as well as of the valve device (9).

 In these figures is also shown the intake zone (4) which is constituted by an orifice traced in the lateral flange (8), this orifice communicates through orifices calibrated directly with the first intake chamber (I2).

The valve device (9) and more precisely the piston (in) is specially drilled so that on the one hand it can receive and @ be made integral with the output shaft (il) and on the other hand an orifice (I4 ) suitable for allowing the escape of the liquid or compressible fluid used. It should be noted in this case that the delivery zone (5) is
constituted by this orifice (I4) which is itself extended by an axial orifice (I5) formed in the output shaft (II).

 Furthermore, the part of the output shaft opening out to the sealed enclosure (3) is pierced with an orifice (I6) substantially perpendicular to the axis of the output shaft (II) and positioned so that it communicates with its axial orifice (I5). Thus the compressible liquid or fluid admitted into the enclosure (3) can be evacuated by these delivery means thus formed towards the outside of the enclosure (3).

 In this regard, according to the present invention, the driving machine (I) comprises means (I7) for channeling and controlling the flow of liquid and / or compressible fluid out of said sealed enclosure (3) through the exhaust zone (5).

 More precisely, as shown in the figures, the means (I7) for channeling and controlling the flow of the liquid or the fluid consist of a sealed exhaust chamber (I8) traversed axially by the output shaft (li). Sealing is achieved in particular by seals (19 and 20), the technique of which is known to those skilled in the art.

 This exhaust chamber (IS) is connected on the one hand to the working enclosure (3) respectively by the axial duct (I4) of the piston (I0), the axial duct (I5) of the shaft (II) and the transverse conduit (I6) then opening into the interior volume (2I) of the exhaust chamber (I8); and secondly by a conduit (22) passing through the wall of said chamber (I8).

 Thus, it is possible to connect the exhaust chamber (I8) by means of its conduit (22), either to a pipe capable of conveying the pumped liquid and making it flow towards a recovery tank, or in the case of f lu compressible id e to a device Si 1 in ci allowing them to weaken the noise given off by the exhaust.

 Thanks to this arrangement, it will be possible in particular to supply the driving machine with a liquid such as in particular pressurized water and / or a compressible fluid such as compressed air. Indeed, the liquid can be channeled in pipes and not create any external disturbance, in the same way 1 compressed air will be on the one hand stretched in the exhaust chamber and the noise muffled by a silencer device then placed for this purpose .Moreover, the motor machine of the present invention comprises distribution means making it possible to create an alternative movement "back and forth" which can also function well from a liquid under pressure and / or a compressible fluid under pressure.

In this regard, the driving machine (I) of the present invention comprises in combination - means for commuai cati on of the two working chambers, placed at the level of the piston (in), capable of connecting said first and second intake chambers. respectively (I2 and
I3), so that they can cooperate together, and, - temporary sequential sealing means - said means of communication, able to be controlled Iiar the pressure of a liquid and / otl of a compressible fluid whose flow circulates in said enclosure (3) from the intake area (4) to the exhaust area (5) to close off the said means of commuai cati on of the two chambers in order to allow a first intake moving the piston ( IO) in the "go" direction then to unblock the communication means in order to put the two chambers in communication to authorize a second admission moving the piston (I0) in the "return" direction.

More precisely, as shown in detail in FIGS. 2 to 3, these said means of communication of the two working chambers are constituted by at least one orifice (23) passing through the piston (IO) and opening out on each of the faces, respectively (24 and 25), corresponding to the first and b the second intake chamber, respectively (I2 and
I3).

In each of these orifices (23) is mounted, with free sliding, a rod (26) delimiting with the said orifice (23) a calibrated passage between the two chambers (I2 and
I3). This passage is intended to route the pressurized liquid and / or the compressible pressurized fluid according to the operating state of the device (9). This calibration will be such that it authorizes a sufficient flow for proper functioning.
stable and will depend in particular on the pressure of the liquid and / or the fluid, on the flow rate of the flow circulating in the chamber (3).

 However, the rod (26) will have a length "X" at least greater than the width "Y" of the piston (in) so that the ends of the rod can rake in one of the corresponding chambers (I2) or (I3) ; this peculiarity being necessary for the function which will be explained below.

 On the other hand, the temporary sequential sealing means of said communication means are in particular constituted by at least two sealing washers (27) and (28) which are respectively placed on either side of the lateral faces ( 24) and (25) of the piston (10).

 These washers (27,2ss) are carried and spaced by the said pin (s) (26). They are fixed in particular by a traditional screw system which allows the two washers (27) and (28) to be braced by the distance X corresponding to the length of the rod (26).

 These sealing washers (27, 28) are able, in the first operating position as shown in FIG. 2, to produce on the one hand the seal between the first and the second intake chamber, respectively (I2) and ( I3), at the level of the orifices (23) for communication and on the other hand the communication between the second chamber (I3) and the exhaust zone t in particular by means of the orifice (I4) of the piston (IO) .

 In addition, in the second operating state as shown in FIG. (3), the sealing washers (27) and (28) make it possible, on the one hand, to produce the seal between the second intake chamber @ ( I3) and the a''échappeelent zone (5) and on the other hand the communication between the two intake chambers (I2) and (I3) thus allowing the liquid or fluid to be admitted to fill the two chambers in series , and thus to cooperate together.

 According to a preferred embodiment, the communication orifices (23) and the pins (26) are three in number, distributed symmetrically on the piston cylinder (I0). Thus, a good retention of the washers (27) and (28) is obtained and a balanced operation. However, this number could be more or less important depending on the nature of the fluid or liquid and according to the characteristics of the machine.

 Furthermore, the piston (I0) and the sealing washers (27) and (28) are made of metal materials machined so that their contact surfaces are rectified, piston-washer sealing being obtained by metal-to-metal contact. . In this regard, to minimize machining, the washers (27) or (28) and / or the piston (I0) will have bosses making it possible to reduce the surfaces.

 However, these surfaces will be largely dimensioned with respect to the orifices to be closed in order to achieve a suitable seal.

 It should be noted that some of the materials may be treated so as to resist corrosion. For example, in the case of the use of the driving machine (I) of the invention with pressurized water, it will be possible to produce the parts in stainless steel or else to carry out treatments such as chromium plating, zinc plating or cadiage.

 Finally, to authorize the tilting of the piston (I0) and to allow temporary sequential closure of the means of communication of the two chambers, the motor machine (I) of the present invention comprises compressible elastic means arranged at the end of the stroke of said piston ( in) able to combat the force created by the liquid and / or the compressible fluid under pressure and applied to the sealing means. Thus we authorize a sequential tilting at each stroke "go" and "return" of the piston (IO).

 More precisely as shown in the figures, these compressible elastic means are constituted by two compression springs (29) and (30) bearing on each of the lateral flanges respectively (8) and (7) of the working enclosure (3) . These springs are calibrated and arranged according to known techniques so that they can combat the thrust of the piston (IO) by each bearing on the respective flange and on the sealing washers (27) or (28) in order to toggle the communication state of the chambers and reverse the movement of the piston (I0).

The operation of the machine (I) of the present invention is as follows
- PRE @ IERE AD @ ISSION: The liquid and / or the compressible fluid circulates from the intake zone (4) to the first intake chamber (12), presses the washer (27) against the piston (I0), closing off the communication orifices (23) as shown in Figure 2.

Thus the sealing washer (28) is pushed by the pins (26) and therefore is not in contact with the face (25) of the piston (I0), the orifice (I4) therefore connecting the second chamber (I3) to the exhaust chamber (I8). Thus the piston (I0) moves in the "go" direction as shown by the arrow (31) in FIG. 2.

When the piston (in) approaches the flange (7) of the enclosure (3) the sealing washer (28) comes into contact with the compression spring (30) which combats the thrust of the piston and allows the tilting of the condition of the valve device (9).

 - SECOND AD @ ISSION The washer (28) closes the exhaust orifice (shot), pushing through the pins (26), and causes the takeoff of the washer (27) as shown in Figure 3 .

Thus the liquid and / or the fluid is admitted into the second intake chamber (I3) via the chamber (12) and causes reverse pressure on the piston (IQ) which causes it to move in the return direction shown diagrammatically by the arrow ( 32) of Figure 3.

The calibration of the communication orifices (23) and the washers (27) and (28) being such, the movement continues in a stable manner and moves the piston towards the other flange (8).

When the washer (27) comes into contact with the compression spring (29), the latter will combat the thrust of the piston then will toggle the state of the valve device (9) so as to return to a first intake phase and and so on.

 Thus during the operation of the machine (I) of the present invention during the "go" movement there is a simultaneous admission and exhaust and during the "return" movement there is an admission into the second chamber, the valve device (9 ) being produced in such a way that it removes all the intermediate sealing parts in order to obtain a frank tilting during changes of state and stable operation not hampered by these intermediate sealing parts.

 Thanks to the arrangements which have just been described, there is therefore a driving machine which can be used for the drive of any mechanical device from the alternative movement.

 For example, as shown in FIG. 1, the driving machine (I) drives a pump (2) for transferring more or less viscous liquids. Thus a motor pump group is produced which will in particular be explosion-proof because it does not create heating or sparks.

 The pump (2) will be constituted according to techniques known to those skilled in the art and for example will include an inlet chamber (31) for the liquid to be transferred and 'a discharge chamber (32), the inlet s' effecting through an orifice (33) while the discharge will be made through the orifice (34).

 In addition, the pump will include a suction valve (35) produced according to a known technique and comprising at least one ball (36) and a spring (37), the ball being capable of sealing between the chamber (31) and the orifice (33).

Likewise the pump will include a discharge valve (38) which by means of a ball (3) and a spring (40) will allow sealing between the intake chamber (31) and the discharge chamber. (32).

 The identified mechanical connection (4I) makes it possible to join the shaft (II) of the machine (I) to the discharge valve (38) of the pump (2).

 This allows in particular the following operation during the "outward" stroke of the piston (I0), the shaft (II) drives the valve (38) by creating a depression in the chamber (31) which causes the suction of the liquid to be transferred through the orifice (33) and the valve (35). Simultaneously, the liquid to be transferred which was contained in the cooling chamber (32) is discharged through the orifice (34).

 When the piston returns (ID? The valve (38) returns to its initial position. This means that the liquid to be transferred which is included in the chamber (31) is compressed, which causes on the one hand the blocking of the valve intake (35) and on the other hand a second delivery of the liquid to be transferred due to the pressure which acts on the ball (39) and the spring (40) opening the valve (38).

 Naturally, other types of pumps and even other types of mechanical devices could be associated with the drive machine of the present invention.

Of course, other embodiments, to the
scope of the art, could have been envisaged without
however go beyond the framework of this one.

Claims (8)

 intake moving the piston (lo) in the "return" direction.  communication between the two rooms to authorize a second  to unclog the means of communication so due to put in  intake moving the piston (IO) in the "go" direction then  communication of the two chambers in order to authorize a first  towards the exhaust zone (5) to obstruct the means of  circulates in said enclosure (3) of the intake area (4)  a liquid and / or a compressible fluid whose flow  - temporary sequential sealing means of said means of communication capable of being controlled by pressure  that they can cooperate together, and,  first and second intake chambers (I2, I3) for  placed at the level of the said piston (IO), capable of connecting the said  - means of communication of the two working chambers,  it includes:  of second admission (I3), c a r a c t e r i sée by the fact  said first admission chamber (I2), the other said chamber  enclosure (3) dividing it into two working chambers, one  outlet (II), mounted with sealed sliding in the said  with valve (9) comprising a piston (IO), integral with a shaft  creates an alternative "round trip" movement, the so-called device  delivery (5) and in which a valve device (9)  sealed (3) having an intake zone (4) and a  more or less viscous liquids, comprising an enclosure  driving of explosion-proof transfer pumps (2)  compressible under pressure in particular used for  I. liquid or fluid driving machine (I)  2. Driving machine according to claim I,  it is because the means of  communication consist of at least one orifice (23)  crossing the piston (IO) and emerging on each of its  faces (24, 25) corresponding to the first and second  inlet chamber (12,13), orifice in which is mounted  free sliding a rod (26) delimiting with the said orifice  (23) a calibrated passage between the two chambers (I2, I3), the so-called  rod (26) having a length "X" at least greater than the  width "Y" of said piston (IO) so that the ends of the  freelance (26) lead into one of the chambers (I2) or (I3).  3. A driving machine according to claim 2, because it is affected by the fact that the sealing means  temporary sequential of said means of communication are  consisting of at least two sealing washers (27) and  (2 (3) placed on either side of the side faces (24) and  (25) of said piston (IO), carried and spaced by said rod  (26), suitable either on the one hand for sealing between the  first and second chamber (I2) and (I3) as well as the  communication between the second room (I3) and the area  exhaust (5) at the orifice (23) of communication,  on the other hand to achieve the seal between the second  intake chamber (I3) and the exhaust zone (5) as well as  the communication between the two intake chambers (12) and (13).  4. Motor machine according to claim I, ca r a c t é r i s e in that it comprises means  compressible elastic arranged at the end of the said piston  (in) able to combat the force created by the liquid and / or the  compressible fluid under pressure, and applied to the means  shutter to switch them sequentially each time  "go" and "return" stroke of the piston (IO).  5. Driving machine according to claims 3  and 4, it is because the means  compressible elastics consist of two springs  compression (29,30) calibrated based on each of  lateral flanges (8,7) of said working enclosure (3) and  able to combat the thrust of the piston as well as to take support  on one of the two sealing washers (27) and (28) in order to  toggle the communication state of the rooms (I2) and  (I3) and reverse the movement of the piston.  6. Driving machine according to claim I, c ar a c t é r i s e in that it comprises means  (I7) to channel and control the flow of the liquid and / or  compressible fluid escaping from said enclosure  sealed (3) by the exhaust zone (5).  7. A driving machine according to claim 6, c a r a c t e r i s e in that the means (I7) for  channel and control the flow of liquid or fluid  outside 1 t enclosure (3) consist of a chamber  sealed exhaust (I8) axially traversed by the shaft of  outlet (II), connected on the one hand to the working enclosure (3) by  conduits (I4, I5, I6) arranged internally to said  shaft (II) and piston (IO), and on the other hand connected by a  conduit (22) passing through the chamber (will) and emerging  externally to an external circuit.  8. Driving machine, according to any one of  previous claims, it is in fact  that the piston (IO) and the sealing washers (27) and (28)  are made of machined metallic materials such as  their contact surfaces are rectified, the sealing  piston-washers being produced by metal-to-metal contact.