The present invention concerns a volumetric pump which may be used in different fields such as medical drug or fluid delivery (infusion Pump, IV pump, enteral pump, parenteral pump) or food, chemical or other industry, for example in conjunction with a compressor or an internal combustion engine. Piston pumps with fluid modules are already part of the prior art. US 2004/101426 discloses a device comprising a cylindrical piston chamber whose upper and lower ends' profile have a specific gradient, said piston chamber containing a rotatable and axially movable pump piston. The profile of the upper and lower end surfaces of the piston has been determined to run concomitantly in contact with the respective two end surfaces of the chamber as the piston rotates. This rotation causes the piston to move alternately upwards and downwards permitting one-way suction and one-way propulsion of a fluid respectively into and out of the pump chambers. The rotational movement of the piston acts as a valve opening and closing alternately the inlet and outlet ports. The drawback of such system results essentially from the difficulties encountered when assembling the piston with the cylindrical chamber.
GB 2060131, U.S. Pat. No. 4,767,399 and U.S. Pat. No. 4,850,980 disclose a pumping mechanism device whose suction and propulsion phases are achieved by means of a bidirectional linear movement of a piston inside a chamber. Unlike US 2004/101426, such pumping mechanism has a device acting as a valve on the inlet/outlet ports which is independent of the piston's movement. Accordingly, the movement of the valve as well as its synchronization with the piston's movement requires more parts thus increasing the cost of the pumping mechanism.
The aim of the present invention is to propose a low cost volumetric pump constituted of a reduced number of parts and having a trouble free assembly of the piston with the chamber.
This aim is achieved by a volumetric pump as set out in claim 1. This volumetric pump comprises at least one piston in a hollow cylinder, the pump having at least one inlet port through which a liquid can be sucked into a pump chamber during an instroke of said piston, and at least one outlet port through which the liquid can be expelled during an outstroke of the piston. The piston or the hollow cylinder can be actuated directly or indirectly by a rotor. This rotor transmits on the one hand a bi-directional linear movement to the piston or to the cylinder and on the other hand, a bi-directional angular movement either to the piston or to another rotable element in order to open and close alternately the inlet and outlet ports.
Unlike US 2004/101426, the combined bidirectional linear and angular movement transmitted by the rotor has for consequence to deliver a steady fluid rate of flow from the volumetric pump. Furthermore, this volumetric pump is highly accurate as the amount of fluid delivered by said pump is closely related to the relative position between the piston and the hollow cylinder housing.
The invention will be better understood thanks to the following detailed description of several embodiments with reference to the attached drawings, in which:
a shows a detail of
a is an axially sectioned rear view of
a is an axially sectioned rear view of
a is an axially sectioned rear view of
a is an axially sectioned rear view of
a is a perspective view of said piston head connected to the shaft of the rotor.
b is a perspective view of the piston of the second embodiment of the invention.
a is a perspective bottom view of the third embodiment showing the outside of the volumetric pump without the rotor.
a is a perspective view of another rotable element fitted into the cylindrical part of
a is an end view of
a is an end view of
a is an end view of
a is an end view of
a is an axially sectioned view of
a is an axially sectioned view of
According to the preferred embodiment of the invention,
As shown by
Shaft (6) transmits the movement of the piston (2) inside cylinder (3) as described below, while the spring (7) insures a smooth articulation of the extremity (8) inside the receptacle (9). Spring (7) is compressed when the piston (2) reaches the ends of the suction and propulsion strokes (
When the piston (2) is in the suction or propulsion cycle (
The bidirectional angular movement of the piston (2) acts as a valve for inlet and outlet ports (10, 11) that are located on opposite sides of the hollow cylinder (3). Piston (2) contains two channels (12,13), which cause the inlet port (10) and the outlet port (11) to open and close alternately while the piston (2) moves angularly. At first, the instroke (or upstroke) of the piston (2) opens the inlet port (10) and closes the outlet port (11), sucking a fluid (15) from the inlet port (10) through the first channel (12) into the lower part of the hollow cylinder (3) (
Said channels (12, 13) have been curve-shaped according to both bidirectional angular and linear movement of the piston (2) in order to ensure a constant opening of the inlet (10) and the outlet (11) during respectively the instroke phase and the outstroke phase of piston (2). This ensures a constant flow of liquid (15) from the inlet port (10) through the piston (2) to the lower part of the cylindrical chamber (3′) during the instroke of piston (2) and a constant flow of the liquid (15) from the lower part of the pump chamber (3′) to the outlet during the outstroke of the piston (2).
Several specifically shaped gaskets or standard Orings (14) are positioned around the inlet port (10) and the outlet port (11) in order to seal off the existing play between the external diameter of the piston (2) and the internal diameter of the cylindrical chamber (3′). Said gaskets, which comprise specific sealing rib design, are part of the piston (2) or cylinder (3).
The present invention may be adapted for medical use as a parenteral system. The piston (2) and the cylindrical chamber (3′) can constitute a disposable. Unlike existing pumps with disposables composed by soft parts such as a flexible membrane or tube as in a peristaltic pump, the disposable piston (2) and cylindrical chamber (3′) can be produced by injection molding methods as hard plastic parts and are therefore not influenced by pressure and temperature. As a result, such system allows an accurate release of a specific amount of a drug by a preset angular shift of the rotor (5). A single dose is produced by a 360° rotation of said rotor (5). Several doses can be released with such system at fixed intervals of time by simply actuating the rotor.
In the second embodiment of the present invention (
In the third embodiment, (
A shaft (not shown) is inserted into the hole (25), said shaft being mounted on a rotor (5), as described in the first embodiment of the invention, for transmitting to the disc (24) a combined bi-directional linear and angular movement.
Such movement of the disc (24) causes the cylindrical housing (22) to slide back and forth following the axis of the two pistons (20, 21) while closing the inlet and outlet ports (10, 11) so as to ensure on the one hand an alternate sucking of the fluid (15) from the inlet port (10) to respectively the first and second chamber (26, 26′) and on the other hand an alternate expelling of the fluid (15) from respectively the first and second chambers (26, 26′) to the outlet port (11).
The optimum synchronization of the suction and propulsion phases between the two chambers (26, 26′) is achieved by a first and a second T-shaped channel (27, 27′) located inside the disc (24) and in its inlet/outlet as shown by
In a fourth embodiment of the invention, the combined bidirectional linear and angular movement of the piston (2) is imparted by mean of an axe (28) which passes through an upper part (29) rigidly connected with the piston head (17) as shown by
Such transmission can be adapted to the third embodiment of the invention (
In a further embodiment of the present invention (not shown in the drawings), the pump (1) is actuated by two rotors (5, 5′) operatively connected to the upper and lower parts of said piston (2) as described in the first embodiment. The first rotor (5) transmits to the piston (2) the movement required by the suction phase while the second rotor (5′) transmits to said piston (2) the movement required by the propulsion phase.
All embodiments of the present invention can be adapted so as to dissociate the relative linear movement of the piston with its angular movement. The linear movement can be transmitted by a first rotor and the angular movement can be transmitted by a second rotor. The movement of the piston can be converted from a linear movement to an angular movement at any time of its stroke.
In another variant of the present invention, the pump (1) can be used as a compressor. A sealed tight tank can be fitted on the outlet port, sucking the air through the inlet (10) into the chamber and propelling the air into the tank by the same mechanism described in the first embodiment.
The mechanism of this volumetric pump (1) can also be adapted for an internal combustion engine. Thus, another aspect of the invention is an internal combustion engine comprising a volumetric pump according to the invention, as described herein.
Although the present invention has been described with reference to specific embodiments, this description is not meant to be construed in limiting sense. Various other fields of application of the invention can be contemplated without departing from the scope of the invention as defined in the appended claims.
Number | Date | Country | Kind |
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PCT/IB2004/003906 | Nov 2004 | IB | international |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2005/002423 | 8/12/2005 | WO | 00 | 5/1/2007 |