VOLUMETRIC PUMP COMPRISING A DRIVING MECHANISM

Abstract

A volumetric pump comprises at least one piston inside a cylindrical housing and means to cause a relative to-and-fro linear movement between the cylindrical housing and the piston in order to produce a stroke of the volumetric pump. This pump further comprises a bi-directional angular rotatable disc acting as a valve which connects alternately at least one inlet port and at least one outlet port to a least one pump chamber located inside the housing, and a driving mechanism arranged to dissociate at least partially the bi-directional angular movement of the rotatable disc with the to-and-fro linear movement of the housing. This driving mechanism is arranged such that the rotatable disc reaches an angular position at which it opens and/or closes the inlet and/or outlet ports when there is no relative to-and-fro linear movement between the cylindrical housing and the piston.

Description

The present invention concerns a volumetric pump comprising a driving mechanism ensuring the delivery of precise amounts of fluids.

Piston pumps, which are part of the prior art, include generally a driving mechanism actuated by a rotor so as to transform the angular motion of said rotor into a bi-directional linear and angular movement of the piston. In one embodiment, WO2006/056828 discloses a volumetric pump comprising a first piston inside a first hollow cylindrical part. This pump has an inlet port through which a liquid can be sucked into a pump chamber during an instroke of the piston and an outlet port through which the liquid can be expelled during the outstroke of the piston. A second piston is positioned opposite to the first piston inside a second hollow cylindrical part, both cylindrical parts being assembled end-to-end facing each other to form a housing. A rotatable element which comprises the inlet and outlet ports is mounted midway inside said housing. Said element is arranged to be animated by a combined bidirectional linear and angular movement to cause relative to-and-fro sliding between the cylindrical housing and the pistons along the axis of said pistons while closing the inlet and outlet ports synchronically to ensure a continuous flow delivery.

The major drawback of this pump stems from the fact that a rotor transmits to the rotatable element a combined bidirectional linear and angular movement. As a consequence, the pistons are still moving relatively to the housing during the opening and the closing of the inlet and outlet ports thus producing a pump stroke that is not truly precise.

The aim of the present invention is to propose a volumetric pump comprising an improved driving mechanism, operated preferably by a single rotor, which ensures no pumping movement during the opening and/or the closing of the inlet and/or the outlet ports. Such pump allows a bigger valve commuting angle which authorizes designing smaller pump mechanisms and disposables. It also creates a more precise pump stroke, leading to a more accurate delivered volume of a fluid.

This aim is achieved by a volumetric pump such as set out in claim 1. This volumetric pump comprises at least one piston inside a cylindrical housing and means to cause a relative to-and-fro linear movement between the cylindrical housing and the piston in order to produce a stroke of the volumetric pump. This pump further comprises a bi-directional angular rotatable disc acting as a valve which connects alternately at least one inlet port and at least one outlet port to a least one pump chamber located inside the housing, and a driving mechanism is arranged to dissociate at least partially the bi-directional angular movement of the rotatable disc with the to-and-fro linear movement of the housing. This driving mechanism is arranged such that the rotatable disc reaches an angular position at which it opens and/or closes the inlet and/or outlet ports when there is no relative to-and-fro linear movement between the cylindrical housing and the piston.

The invention will be better understood thanks to the following detailed description of several embodiments with reference to the attached drawings, in which:

FIG. 1 represents a perspective top view of the volumetric pump in transparency without the driving mechanism

FIG. 2 represents a perspective view of one of the two cylindrical parts constituting the hollow cylindrical housing.

FIG. 3 represents a front view and a side view of the rotable disc.

FIG. 4 represents a cross-sectional view of the rotable disc taken on the line C-C in FIG. 3.

FIG. 5 a represents an end view of FIG. 1 and FIG. 5b a cross-sectional view taken on the line A-A in FIG. 5a at the beginning of a cycle.

FIG. 6 a represents an end view of FIG. 1 and FIG. 6b a cross-sectional view taken on the line A-A in FIG. 6a after a 90° rotation of a rotatable member which is part of the driving mechanism.

FIG. 7 a represents an end view of FIG. 1 and FIG. 7b a cross-sectional view taken on the line A-A in FIG. 7a after a 180° rotation of the rotatable member.

FIG. 8 a represents an end view of FIG. 1 and FIG. 8b a cross-sectional view taken on the line A-A in FIG. 8a after a 2700 rotation of the rotatable member.

FIG. 9 represents a perspective view of the driving mechanism of the volumetric pump according to the first embodiment of the present invention.

FIG. 10 represents a partial perspective view of the driving mechanism of FIG. 9.

FIG. 11 represents a partial perspective view of the driving mechanism like FIG. 10 without the volumetric pump.

FIG. 12 represents a perspective bottom view of FIG. 11.

FIG. 13 represents a longitudinal cross-sectional view of FIG. 10.

FIG. 14 represents a cross-sectional view taken on the line C-C of FIG. 13.

FIG. 15 represents a perspective view of the rotatable member whose angular movement is transmitted by a rotor through a transmission belt.

FIG. 16 represents a graph depicting the evolution of the valve sequence produced by the angular movement of the rotatable element of an improved mechanism over a standard mechanism relative to the magnitude of a pump stroke.

FIG. 17 represents a partial bottom view of the improved mechanism when the rotatable member is about to rotate anticlockwise.

FIG. 18 represents a partial bottom view of the improved mechanism when the rotatable member is about to rotate clockwise.

FIG. 19 represents a perspective view of the driving mechanism of the volumetric pump according to a second embodiment of the present invention.

FIG. 20 represents a longitudinal cross-section view of FIG. 19.

FIG. 21 represents a perspective view of the driving mechanism like FIG. 19 without the volumetric pump.

FIG. 22 represents a top view of FIG. 21.

FIG. 23 represents a bottom view of FIG. 21.

FIG. 24 represents a movement transmission from the rotor to the rotatable element according to a variant of the first two embodiments.

FIG. 25 represents a perspective view of the driving mechanism according to another embodiment of the present invention.

FIG. 26 represent a front view of FIG. 25.

According to a first embodiment of the invention, a pump, similar to the pump described in one embodiment of WO2006/056828, comprises a driving mechanism as described hereafter.

Such pump comprises a first and a second piston (1, 1′) fixedly positioned opposite to each other inside a hollow cylindrical mobile housing (2) as shown by FIG. 1. Said housing (2) is made up of two identical cylindrical parts (3, 3′) assembled end-to-end facing each other. A disc (4) (FIGS. 3 and 4) comprising inlet and outlet ports (5, 5′) located preferably at 180° from each other is mounted midway inside said housing (2) between the two cylindrical parts (3, 3′). Such assembly creates a first and a second chamber (6, 6′). The disc (4) is angularly movable relative to the housing (2) and actuated by the driving mechanism through a shaft as described later on.

Unlike the volumetric pump described in WO2006/056828 where the spherical extremity (7) of a shaft (8) is inserted into a hole located beneath the disc (4) in order to transmit a combined bi-directional linear and angular movement to said disc (4), the volumetric pump of the present invention comprises a disc (4) which has been modified so as to be adaptable to the driving mechanism of the present invention. Such disc (4) comprises on its bottom part an aperture (10) along its entire width, said aperture (10) having a half cylindrical-shaped recess (11) along which the spherical extremity (7) of the shaft (8), which is part of the driving mechanism, can slide while said driving mechanism is operating thus preventing the shaft (8) to transmit also a bidirectional linear movement to the disc (4) that would cause the housing (2) to slide to-and-fro along the axis of the piston (1, 1′). The bi-directional linear movement of the housing (2) along the axis of said pistons (1, 1′) is transmitted by the driving mechanism as set out afterwards.

By the combined linear movement of the cylindrical housing (2) and angular movement of the disc (4), the cylindrical housing (2) slides back and forth following the axis of the two pistons (1, 1′) while closing the inlet and outlet ports (5, 5′) so as to ensure on the one hand an alternate sucking of a fluid from the inlet port (5) to respectively the first and second chamber (6, 6′) and on the other hand an alternate expelling of the fluid (12) from respectively the first and second chambers (6, 6′) to the outlet port (5′).

The synchronisation of the suction and propulsion phases between the two chambers (6, 6′) is achieved by first and second T-shaped channels (13, 13′) located inside the disc (4) as shown by FIG. 4. Channels (13, 13′) connect alternately the inlet port (5) to the first and second chamber (6, 6′), and the first and second chamber (6, 6′) to the outlet port (5′) when said channels (13, 13′) overlap alternately a first and a second opening (14, 14′) located on the end of both cylindrical parts (3, 3′) as shown by FIG. 2 for the part (3).

To avoid any pumping movement when the inlet and/or outlet ports (5, 5′) open or close, the driving mechanism comprises a rotatable member (9) contained by two ball bearings (9′) (FIGS. 13 and 14). This rotatable member (9) is actuated by a rotor (19) which transmits through a transmission belt (20) an angular movement to a circular-shaped pulley (21) which is part of said rotatable member (9). The latter is transverse along its entire height by a shaft (8) positioned eccentrically. A liner and a rotation bearing (8″) are mounted around the shaft (8) so that the latter can freely rotate about its own axis (8′). One extremity of the shaft (8) is adapted to transmit the bi-directional angular movement to the disc (4) of the volumetric pump as described above so as to open and close appropriately the inlet and outlet ports (5, 5′) of said volumetric pump.

The driving mechanism further comprises a connecting-piece (15) which is connected at one end around a ring (15′) whose axis (15″) is angularly positioned forward to the shaft (8)'s axis (8′), the other end of said connecting-piece being connected to a first intermediate element (22). This connecting-piece (15) converts the rotating movement of the rotatable member (9) into a bi-directional linear movement of a block constituted of a cage (16) whose two sides are connected to the first and a second intermediate element (22, 22′). Each side of each intermediate element (22, 22′) is slidably mounted on two parallel rods (23).

The cage (16) transmits the bidirectional linear movement to a movable support (17), the latter being slidably mounted inside the pump cage (16). The housing of the volumetric pump is fixedly adjusted into the support (17) while a shaft (24, 24′) passes through each piston (1, 1′) to fixedly connect said piston (1, 1′) to a non-movable element (25, 25′). A lateral play (17′) is provided between the pump cage (16) and said support (17) in order to delay the sliding movement of the support (17) and consequently the linear movement of the housing (2) of the volumetric pump.

The linear movement of the housing (2) along the pistons (1, 1′) must be synchronized with the angular movement of the rotatable element (4) to ensure that there is no pumping movement during the opening and/or the closing of the inlet and/or outlet ports (5, 5′) whatever be the initial position of the cage (16) and the direction of rotation of the rotatable member (9). FIG. 16 depicts the evolution of the valve sequence produced by the angular movement of the rotatable element (4) of an improved mechanism over a standard mechanism relative to the magnitude of a pump stroke. The commuting sequence of the valves, when operated with the improved mechanism, is represented by the shading areas located around the abscissa.

In order to coordinate the commuting sequence of the valves with the so called “Idle pumping stage” (FIG. 16) where no pumping movement occurs and which corresponds to the lateral play (17′) which is provided between the pump cage (16) and said support (17) as described above, a play is provided by a groove (40) (FIGS. 17 and 18) in order to shift the sinusoidal curve from an angle such that the beginning of the closing sequence of the inlet or outlet ports (5, 5′) occurs as soon as the volumetric pump reaches the end of a stroke. Such angle delays the closing and opening sequences such that they occur only during the idle pumping stage. This ensures that the complete opening sequence of the inlet or outlet ports (5, 5′) occurs just before the next stroke produced by the sliding movement of the housing (2) along the other piston (1, 1′). With the standard mechanism the valves would still commute while the pumping movement would still occur, thus producing a pump stroke that is not truly precise.

This groove (40) creates a reversible mechanism which is independent both of the position of the pump cage (16) and the direction of rotation of the rotatable member (9) (FIGS. 17 and 18). This play is twice the angle required to complete an opening or a closing sequence of the inlet or outlet ports (5, 5′).

As the shaft (8) is eccentrically mounted on the rotatable member (9), the bidirectional linear movement transmitted to the housing (2) of the volumetric pump is not constant as it follows a sinusoidal curve. In order to ensure a constant flow delivery, the driving mechanism must be put under servo to ensure constant linear movement.

In a second embodiment of the present invention (FIGS. 19, 20, 21, 22 and 23), the to-and-fro linear movement is transmitted directly by the rotatable element (9) to a part of the support (17) of the cylindrical housing (2) without the need of the connecting-piece (15), the first and second intermediate elements (22′ 22′) and the pump cage (16). Unlike the first embodiment, a ball bearing (42) is assembled around the upper part of the shaft (8) between two contact surfaces (43) part of the disposable supports (17). The distance between these two contact surfaces (43) is wider than the ball bearing (42) external diameter in order to create the lateral play (17′) to make sure that no pumping movement occurs when the inlet and/or outlet ports (5, 5′) open or close.

In a variant of the first and second embodiments of the present invention, the circular-shaped pulley (21) which is part of the rotatable member (9) is replaced by an elliptical-shaped pulley (not shown). The circumference of this pulley has been calculated so as to turn the inconstant linear movement of the housing (2) into a constant linear movement to ensure a constant flow delivery. The use of the elliptical-shaped pulley avoids putting the driving mechanism under servo.

In another variant of these two embodiments, the rotatable element (9) has an external toothed diameter (45) which meshes with a worm screw (44) directly driven by the rotor (19).

In a fourth embodiment of the invention (FIGS. 25 and 26), the driving mechanism comprises a stator (26) containing a square-shaped groove (27) having a specific radius on each corner. A first needle bearing (28) rests on the bottom of the groove (26) while a second needle bearing (29), into which a disposable shaft (30) is inserted, rests on the first one. A disc (31) is rotatably connected to the center of the stator (26) and is driven by a rotor (not shown) through a transmission belt (32). Said disc (31) has an aperture (33) through which the second needle bearing (29) is positioned. A lateral play between the second needle bearing (29) and the edge of the aperture (33) allows the disc (31) to drag the shaft (30) along the groove (27). The course of the shaft (30) is given by the first needle bearing (28) which rolls along the groove (27) while the disc (31) is dragging the second needle bearing (29) holding the shaft (29).

Although the present invention has been described with reference to specific embodiments, this description is not meant to be construed in limiting sense.

Claims

1-14. (canceled)

15. A volumetric pump comprising on the one hand at least one piston inside a cylindrical housing and means to cause a relative to-and-fro linear movement between the cylindrical housing and the piston in order to produce a stroke of the volumetric pump and on the other hand a preferably bi-directional angular rotatable element acting as a valve which connects alternately at least one inlet port and at least one outlet port to at least one pump chamber located inside the housing, and a driving mechanism that is arranged to dissociate at least partially the bi-directional angular movement of the element with the relative to-and-fro linear movement between the housing and the piston, the driving mechanism being arranged such that the rotatable element opens and/or closes the inlet and/or outlet ports when it reaches an angular position at which there is no or substantially no relative to-and-fro linear movement between the cylindrical housing and the piston, wherein the driving mechanism comprises a rotatable member having an eccentric shaft, one of whose ends is adapted to transmit the bi-directional angular movement to the rotatable element of the volumetric pump so as to open and close appropriately the inlet and outlet ports of said volumetric pump, the driving mechanism further comprising at least one connecting-piece connected at or near to the other end of the shaft, such that said piece is adapted to convert indirectly the rotary motion of the rotatable member into a bi-directional linear movement of the housing of the volumetric pump along the axis of the pistons.

16. A volumetric pump according to claim 15, wherein the bi-directional linear movement of the housing transmitted by the connecting-piece of the driving mechanism is transmitted through a pump cage to a support, the latter being slidably mounted inside the pump cage, said support being adapted to receive the volumetric pump.

17. A volumetric pump according to claim 16, wherein the pump cage and the support of the driving mechanism are arranged so that there is a lateral play between said cage and said support in order to delay the sliding movement of the housing to ensure no pumping movement of the volumetric pump during the opening and/or the closing of the inlet and outlet ports.

18. A volumetric pump according to claim 15, comprising a first fixed piston inside a first hollow cylindrical part and a second fixed piston positioned opposite to the first piston inside a second hollow cylindrical part, both cylindrical parts being assembled end-to-end facing each other to form the housing, the rotatable element being mounted midway inside the housing, said rotatable element being movable with a bi-directional angular movement such that it acts as a valve connecting on the one hand the inlet port alternately to a first and second chamber into which a fluid can be sucked through a first channel during a pump instroke and connecting on the other hand an outlet port alternately to said first and second chamber where the fluid can be expelled through a second channel during a pump outstroke, said pump instroke and outstroke being produced by the linear sliding movement of the housing along the pistons.

19. A volumetric pump according to claim 15, wherein the driving mechanism comprises a single rotor transmitting through a transmission belt an angular movement to a pulley which is connected around the rotatable member.

20. A volumetric pump according to claim 19, wherein the pulley of the driving mechanism has a circular shape.

21. A volumetric pump according to claim 19, wherein the pulley of the driving mechanism has an elliptical shape.

22. A driving mechanism for a volumetric pump according to claim 15, comprising a rotatable member having an eccentric shaft one of whose ends is adapted to transmit the bi-directional angular movement to the rotatable element and a connecting-piece connected at or near the other end of the shaft, said piece converting indirectly the rotary motion of the rotatable member into a bi-directional linear movement of the housing of the volumetric pump along the axis of the pistons.