阅读说明：本技术 微型泵 (Micro pump ) 是由 法比安·波利 亚历山大·佩里尔 托马斯·怀斯 于 2018-12-10 设计创作，主要内容包括：一种泵,包括：-定子(4)；-转子(6),其至少部分可滑动且可旋转地安装在定子中,转子包括具有第一直径(D1)的第一轴向延伸部和具有第二直径(D2)的第二轴向延伸部(26),第二直径大于第一直径；-第一阀门,其由第一阀门密封件(18)与转子中的第一通道(42)一起形成,该第一阀门密封件围绕第一轴向延伸部安装在定子上,该第一通道构造成当第一阀门处于打开位置时,允许流体越过第一阀门密封件连通,-第二阀门,由第二阀门密封件(20)与转子中的第二通道(44)一起形成,该第二阀门密封件围绕第二轴向延伸部安装在定子上,该第二通道构造成当第二阀门处于打开位置时,允许流体越过第二阀门密封件连通,以及-泵室,其形成于转子和定子之间以及第一阀门密封件和第二阀门密封件之间。该泵还包括起动致动器(30),该起动致动器安装在定子的壳体上并且可从锁定运行位置移动到起动位置移,该起动致动器构造成与转子接合,并将转子从第一阀门和第二阀门中的至少一个关闭的运行位置轴向地移动到第一阀门和第二阀门均打开的起动位置。(A pump, comprising: -a stator (4); -a rotor (6) at least partly slidably and rotatably mounted in the stator, the rotor comprising a first axial extension having a first diameter (D1) and a second axial extension (26) having a second diameter (D2), the second diameter being greater than the first diameter; -a first valve formed by a first valve seal (18) mounted on the stator around the first axial extension, together with a first passage (42) in the rotor configured to allow fluid communication past the first valve seal when the first valve is in an open position, -a second valve formed by a second valve seal (20) mounted on the stator around the second axial extension, together with a second passage (44) in the rotor configured to allow fluid communication past the second valve seal when the second valve is in an open position, and-a pump chamber formed between the rotor and the stator and between the first valve seal and the second valve seal. The pump also includes a priming actuator (30) mounted on the housing of the stator and movable from a locked operating position to a priming position, the priming actuator configured to engage the rotor and axially move the rotor from an operating position in which at least one of the first and second valves is closed to a priming position in which both the first and second valves are open.)

1. A pump, comprising:

-a stator (4),

-a rotor (6) mounted at least partially slidably and rotatably in the stator, the rotor comprising a first axial extension (24) having a first diameter (D1) and a second axial extension (26) having a second diameter (D2), the second diameter being greater than the first diameter;

-a first valve (V1) formed by a first valve seal (18) mounted on the stator about the first axial extension, together with a first channel (42) in the rotor configured to allow fluid communication past the first valve seal when the first valve is in an open position,

-a second valve (V2) formed by a second valve seal (20) mounted on the stator about the second axial extension, together with a second channel (44) in the rotor configured to allow fluid communication past the second valve seal when the second valve is in an open position, and

-a pump chamber (8) formed between the rotor and the stator and between the first valve seal and the second valve seal,

it is characterized in that the preparation method is characterized in that,

the pump further includes a priming actuator (30) mounted on the housing of the stator and movable from a priming position to a locked operating position, the priming actuator (30) configured to engage the rotor and axially move the rotor from a priming position in which both the first and second valves are open to an operating position in which at least one of the first and second valves is closed.

2. Pump according to any of the preceding claims, wherein the priming actuator (30) comprises a locking mechanism (30) comprising a locking shoulder (36), the locking shoulder (36) engaging with a complementary locking shoulder (37) on the stator housing in the pump operating position.

3. A pump according to any preceding claim, wherein the locking mechanism is releasable to allow the rotor to move from a run position to a start position, the start actuator being configured to engage with the rotor and move the rotor axially from the run position to the start position.

4. A pump according to any preceding claim, wherein the priming actuator is positioned in a locked running position prior to first use.

5. The pump of any of claims 2 to 4, wherein the locking mechanism comprises a pivotable latch (34).

6. The pump according to any preceding claim, wherein the pivotable latch (34) comprises a manually engageable button (35), the manually engageable button (35) being connected to the priming actuator (30) via an integrally formed hinge (41).

7. The pump of claim 2, wherein the locking mechanism is irreversible to prevent the rotor from moving from the run position to the start position such that the rotor is in the start position prior to first use.

8. A pump according to any preceding claim, wherein the priming actuator is slidably mounted on a housing of the stator.

9. Pump according to any one of the preceding claims, wherein the rotor comprises a rotor head (10) formed at the end of a rotor shaft (12), the rotor head comprising an actuating edge (50) extending therearound, the actuating edge comprising an internal axial shoulder (57), the internal axial shoulder (57) being engageable with the actuating shoulder (50) of the priming actuator (30).

10. Pump according to any one of the preceding claims, wherein the actuating edge (50) comprises an external axial shoulder (58), the external axial shoulder (58) being configured to interfere with an edge axial control shoulder (58) provided on the starting actuator (30) to prevent the pump from operating when the starting actuator is in a locked operating position and the rotor is not in the operating position.

11. Pump according to either of the two preceding claims, wherein a cam track (46) is provided on the inner radial portion of the actuating edge and the inner axial shoulder (57), which can be engaged by the actuating shoulder (40), is provided on the outer radial portion of the actuating edge.

12. Pump according to any one of the preceding claims, wherein the rotor first extension comprises a recess (54) close to the free end of said first extension (24), said recess being configured to increase the passage section for the fluid to flow towards the inlet.

13. Pump according to any one of the preceding claims, wherein the priming actuator (30) comprises a head (54), the head (54) extending partially over the head (10) of the rotor to prevent the rotor from moving out of the stator.

14. Pump according to any of the preceding claims, wherein the pump inlet (14) is connected to the pump chamber (8) by means of the first valve (V1) and the pump outlet (16) is connected to the pump chamber by means of the second valve (V2), and wherein the inlet is located at the axial free end of the rotor shaft (12).

15. A pump according to any preceding claim, wherein the inlet extends generally radially from the rotor and the outlet extends generally radially from the rotor.

Technical Field

The present invention relates to a micropump. Micropumps may be used for dispensing small quantities of fluids, in particular for medical applications, for example in drug delivery devices. The micropump in connection with the present invention may also be used in non-medical applications requiring high precision in the delivery of small amounts of fluids.

Background

In EP1803934 and EP1677859, a micropump for delivering small quantities of fluid is described, which micropump can be used in particular in medical and non-medical applications. The micropump described in the aforementioned document comprises a rotor having first and second axial extensions of different diameters, which engage with first and second seals of the stator to form first and second valves that open and close fluid communication across the respective seals as a function of the angular and axial displacements of the rotor. A pump chamber is formed between the first and second seals of the stator, whereby the volume of fluid pumped per revolution of the rotor is a function of the difference in diameter between the first and second rotor axial extensions and the axial displacement of the rotor, which is achieved by the cam system as a function of the angular position of the rotor relative to the stator. The ability to control the pumped volume per cycle as a function of the rotational and axial displacements of the rotor and the diameter difference between the rotational extensions enables very small amounts of fluid to be pumped per revolution of the rotor with high accuracy.

One of the advantageous features of the pump described in the above-mentioned patent is that there is no direct fluid communication between the inlet and the outlet, since the inlet valve and the outlet valve can never be opened simultaneously. This feature ensures safe operation of the pump, particularly in medical applications, so that drug delivery is only possible when the pump is running and fluid is automatically prevented from passing when the pump stops running at any point of the pump.

However, one of the disadvantages of this pump system is that the pump start-up operation can be slow and friction can occur between the pump shaft and the valve seal during initial operation when the pump is empty and therefore dry.

In certain applications, for example for drug infusion through catheter tubing, it is necessary to use a large volume of fluid to prime and remove air from the infusion set compared to the pump circulation volume of the pump as described in EP1803934 and EP 1677859. Therefore, the start-up procedure is not very efficient.

Disclosure of Invention

In view of the foregoing, it is an object of the present invention to provide a micropump which allows a quick and reliable start, but which operates accurately and safely.

It would be particularly advantageous to provide a micro-pump that allows for rapid priming with a fluid delivery system (e.g., an infusion set) downstream of the pump.

Advantageously, a pump is provided that is easy to use and economical to manufacture.

In drug delivery applications, it would be advantageous to provide a pump that can deliver small amounts of fluid with accuracy, reliability, and safety.

The object of the invention is achieved by a micropump according to claim 1.

A pump is disclosed herein comprising

-a stator,

a rotor mounted at least partially slidably and rotatably in the stator, the rotor comprising a first axial extension having a first diameter and a second axial extension having a second diameter, the second diameter being larger than the first diameter,

a first valve formed by a first valve seal mounted on the stator about the first axial extension and a first passage in the rotor configured to allow fluid communication past the first valve seal when the first valve is in an open position,

-a second valve formed by a second valve seal mounted on the stator about the second axial extension, together with a second channel in the rotor configured to allow fluid communication past the second valve seal when the second valve is in an open position, and

-pump chambers formed between the rotor and the stator and between the first valve seal and the second valve seal.

According to the invention, the pump further comprises a priming actuator mounted on the housing of the stator and movable from a priming position to a lock-out operating position, the priming actuator being configured to engage the rotor and axially move the rotor from a priming position in which both the first and second valves are open to an operating position in which at least one of the first and second valves is closed.

The starting actuator may be positioned in a locked operating position prior to initial use and may be movable from the locked operating position to a starting position, the starting actuator being configured to engage the rotor and axially move the rotor from an operating position in which at least one of the first valve and the first valve is closed to a starting position in which both the first valve and the second valve are open. In this embodiment, the locking mechanism is releasable to allow the rotor to move from the run position to the start position.

In an alternative embodiment, the locking mechanism is irreversible to prevent the rotor from moving from the run position to the start position, thereby bringing the rotor to the start position prior to first use.

In an advantageous embodiment, the priming actuator is slidably mounted on the housing of the stator.

In an advantageous embodiment, the priming actuator comprises a locking mechanism comprising a locking shoulder which in the pump operating position engages with a complementary locking shoulder on the stator housing.

In an advantageous embodiment, the locking mechanism comprises a pivotable latch.

In an advantageous embodiment, the pivotable latch comprises a manually engageable push button connected to the priming actuator by an integrally formed hinge.

In an advantageous embodiment, the rotor comprises a rotor head formed at the end of the rotor shaft, the rotor head comprising an actuating edge extending therearound, the actuating edge comprising an internal axial shoulder engageable with an actuating shoulder of the starting actuator.

In an advantageous embodiment, the actuating edge comprises an external axial shoulder configured to interfere with an edge axial control shoulder provided on the starting actuator to prevent the operation of the pump when the starting actuator is in the locked operating position and the rotor is not in the operating position.

In an advantageous embodiment, the cam track is provided on an inner radial portion of the actuating edge and an inner axial shoulder engageable by the actuating shoulder is provided on an outer radial portion of the actuating edge.

In an advantageous embodiment, the rotor first extension comprises a recess near the free end of the first extension, the recess being configured to increase the passage section for the fluid flowing towards the inlet.

In an advantageous embodiment, the starting actuator comprises a head which extends partially over the head of the rotor to prevent the rotor from moving out of the stator.

In an advantageous embodiment, the inlet of the pump is connected to the pump chamber via a first valve and the outlet of the pump is connected to the pump chamber via a second valve, and wherein the inlet is located at the axial free end of the rotor shaft.

In an embodiment, the inlet may extend in a substantially radial direction from the rotor and the outlet may extend in a substantially radial direction from the rotor.

In an advantageous embodiment, the stator is made of an injection-type polymer comprising a first polymer for forming the stator body and a second polymer with elasticity for forming the valve seal.

In an embodiment, the rotor is made of an injection type polymer. In another embodiment, the rotor is made of metal, preferably steel.

Other objects and advantageous features of the invention will become apparent from the claims, the detailed description and the accompanying drawings, in which:

drawings

FIG. 1 is a perspective view of a pump module of a micro-pump according to an embodiment of the present invention;

FIG. 2 is an exploded perspective view of the pump module of FIG. 1;

FIG. 3a is a cross-sectional view of the pump module of FIG. 1;

FIG. 3b is a view similar to FIG. 3a with the rotor of the pump module in a start position;

FIG. 4a is a perspective partial cross-sectional view of the micro-pump of FIG. 1;

FIG. 4b is a view similar to FIG. 4a with the rotor of the pump module in a start position;

FIG. 5a is a detailed partial view of the pump chamber and rotor shaft portion of a pump module according to an embodiment of the invention;

fig. 5b is a view similar to fig. 5a, showing the rotor in a starting position.

Detailed Description

With reference to the figures, the micropump comprises a pump module 2, the pump module 2 comprising a stator 4 and a rotor 6 driven by a rotary drive (not shown) which imparts a rotary motion on the rotor about a rotation axis a. The rotor 6 is biased axially, for example by a spring (not shown), so that a cam system comprising a cam track 46 on the rotor which engages with a complementary cam follower 48 on the stator applies an axial displacement Ax to the rotor relative to the stator, depending on the angular position of the rotor as it rotates. Axial and rotational displacement of the rotor relative to the stator causes first and second valves (described in more detail below) to open and close to effect a pumping action. This general functional principle is known per se and is described, for example, in EP 1803934.

In an embodiment, the pump inlet 14 may be formed at an axial end of the rotor, while the outlet 16 may be disposed towards the end of the rotor comprising the cam. The outlet 16 may extend radially through the stator. The inlet and outlet ports may be reversed depending on the direction of rotation of the rotor relative to the stator and the valve seal configuration. Furthermore, in some embodiments, the pump may also be configured to be bi-directional, whereby the direction of fluid flow is dependent on the direction of rotation of the rotor. The inlet or outlet formed at the axial end of the rotor may also be directed radially through the stator rather than axially from the end of the stator. The skilled artisan will appreciate that the various fluid pathways of the inlet and outlet may be configured as needed for connection to a fluid source and a fluid delivery location without departing from the scope of the present invention.

The rotor 6 has a first extension 24 and a second extension 26, the first extension 24 having a first diameter D1, the second extension 26 having a second diameter D2, the first and second diameters having different values. In the illustrated embodiment, diameter D2 of second extension 26 is greater than diameter D1 of first extension 24. The difference between the first diameter and the second diameter, in combination with the axial displacement of the rotor, defines the pumping volume per revolution of the rotor.

The micro-pump includes a first valve V1 and a second valve V2, the first valve V1 being formed between the rotor first extension and the stator, and the second valve V2 being formed between the rotor second extension and the stator. The first valve V1 and the second valve V2 control the opening and closing of the respective inlet 14 or outlet 16.

The first valve V1 is formed by a first valve seal 18 mounted on the stator and a first channel 42 mounted on the rotor, the first channel 42 configured to allow fluid communication across the first valve seal when the first valve seal is in an open position and not allow fluid communication across the first valve seal when the first valve V1 is in a closed position. The second valve V2 is formed by a second valve seal 20 on the stator 4 and a second passage 44 formed on the rotor 6, the second passage 44 allowing fluid communication across the second valve seal when the second valve V2 is in the open position and not allowing fluid communication across the second valve seal when the second valve V2 is in the closed position. Pump chambers 8 are formed between the rotor 6 and the stator 4 and between the first valve seal 18 and the second valve seal 20. The pump chamber seal 22 circumferentially defines a (circular) second extension 26 and separates the pump chamber 8 from the environment outside the pump.

It is within the scope of the present invention that first and second valve seals 18, 20 may have a variety of configurations and shapes, so long as there is a tilt or axial offset in the seals that allows the first and second passages to pass over the respective seals due to angular and axial displacement of the rotor, respectively, to open and close the first and second valves as needed during the filling and draining stages, without allowing fluid to pass directly between the inlet and outlet.

In the illustrated embodiment, the fluid passages 42, 44 are shown as axially extending grooves in their respective first and second rotor extensions 24, 26. However, in a variant, other fluid passage configurations may be implemented, for example, the passages may not be grooves, but rather may be buried within the rotor and have apertures on the rotor surface that allow communication across the respective seals. It may also be noted that first valve seal 18 may have a different angular orientation relative to second valve seal 20 than the illustrated embodiment, and the position of rotor passages 44, 42 will change accordingly.

The stator may be an injection type component, such as an injection type polymer, having a seal injected therein, such as in a two-step injection process. The seal may be injected into an elastomeric material as known per se in the art. The rotor 6 can also be injected with polymer, the stator and rotor thus forming a low cost disposable part. However, the rotor 6 may also be made of a more durable material, such as steel or another metal. Metal rotors may be advantageous in certain applications to reduce wear or friction and/or increase the dimensional accuracy of the rotor, thereby increasing the accuracy of the pump cycle volume.

According to an aspect of the invention, the pump module 2 further comprises a priming actuator 30, the priming actuator 30 being movably mounted to the housing of the stator 4. The starting actuator 30 is movable from a locking position as shown in fig. 1, 3a, 4a, 5a to a starting position as shown in fig. 3b, 4b, 5 b.

In the locked position, the pump module may be driven to administer fluid by rotating the rotor as described above. During operation of the pump, the first and second valves are never opened simultaneously, and therefore, when the rotor is not being driven, fluid may not flow freely from the inlet 14 to the outlet 16, and vice versa, regardless of the rotational position of the rotor.

A priming operation may be performed to fill the fluid path through the pump and the fluid paths upstream and downstream of the pump, either before the pump is initially used, or after an initial run after the pump is stopped. The passages include the inlet 14, pump chamber 8 and outlet 16, and fluid passages downstream or upstream of the pump. For example, in medical applications where the pump is used to administer a medicament via a catheter tube, the volume of fluid in the passageway to the patient may be significantly greater than the volume of the pump chamber 8, and therefore a priming operation relying solely on pump operation by rotation of the rotor 6 may be time consuming.

In accordance with the present invention, the priming operation opens the valves V1, V2 to allow fluid to rapidly pass through the pump module 2 and the upstream and downstream fluid passages. The starting actuator 30 is configured to engage the rotor 6 to move the rotor 6 axially in a direction to increase the volume of the pump chamber 8 until both the inlet valve V1 and the outlet valve V2 are open. The inlet valve V1 is open when the first passage 42 in the first rotor extension 24 passes through the first valve seal 18, and the outlet valve V2 is open when the second passage 44 in the second rotor extension 26 passes through the second valve seal 20.

In order to reduce the resistance to the through-flow of fluid, the first extension 24 of the rotor may advantageously be provided with a cut away portion or recess 54 at the free end of the rotor shaft 12.

The priming actuator 30 includes a guide track 52a that engages in a complementary guide track 52b on the stator housing, allowing the priming actuator 30 to slide axially relative to the stator housing. The starting actuator further comprises a releasable locking mechanism 32, in the embodiment shown in the form of a push button latch 34, which push button latch 34 comprises a locking shoulder 36, which locking shoulder 36 engages with a locking shoulder 37 on the stator housing.

During operation of the pump module as shown in fig. 3a, 4a and 5a, the priming actuator is in a locked position to prevent the rotor 6 from moving axially out of its operating position. For a priming operation, the locking mechanism 32 may be actuated to disengage its locking shoulder 36 from the housing locking shoulder 37, and subsequently move the priming actuator 30 relative to the stator housing in the priming direction P +. The priming actuator is moved until the actuating shoulder 40 on the priming actuator 30 engages the complementary shoulder 57 on the rotor head 10 and lifts the rotor axially away from the stator in a priming direction P + corresponding to the direction of increasing pump chamber volume, as shown in figures 3b and 4 b.

In the illustrated embodiment, the rotor head 10 comprises an actuating edge 50, the actuating edge 50 having an internal axial shoulder 57, the internal axial shoulder 57 being configured to be engaged by the actuating shoulder 40 of the starting actuator 30. As best shown in fig. 3b, the cam track 46 on the rotor is lifted a distance from the complementary cam follower 48 on the stator. As best shown in fig. 5b, fluid may enter the pump chamber 8 directly from the inlet 14 via the first passage 42 in the rotor first extension 24 and exit via the outlet 16. Thus, during a start-up operation, pressure acting on the fluid entering the inlet 14 by gravity or by the pressure generator may be used to rapidly deliver the fluid through the pump.

Once the priming operation is completed, the priming actuator 30 can be moved back in the locking direction P-to the locking position shown in fig. 3a by a reverse axial sliding of the priming actuator 30 relative to the stator housing.

The stator housing may be provided with an actuation stop 39, the actuator stop 39 being configured to engage with a complementary stop 38 provided on the starting actuator. The locking shoulder 36 of the locking mechanism 32 may also be configured to engage an actuator stop 39 on the stator such that axial displacement of the priming actuator is limited and the priming actuator remains assembled to the stator housing and cannot be removed from the stator housing.

It may be noted that other stop and latch arrangements may be provided which allow locking the starting actuator to the stator housing in the run position and unlocking and displacing it to the start position without departing from the scope of the invention. Those skilled in the art will appreciate that stops may be provided at different locations on the actuator and stator housing, and that there are a variety of locking mechanisms that may be used to secure the mounted first component to the second component. In the illustrated embodiment, the priming actuator 30 is shown slidably mounted to the stator housing and provided as a separate part from the stator housing. However, in a variant, the starting actuator may be rotatably mounted on the stator housing in such a way that rotation of the starting actuator relative to the stator housing causes an axial displacement of the starting actuator, which in turn engages the rotor to lift it from the operating position to the starting position.

In the embodiment shown, the starting actuator 30 comprises a head portion 54, which head portion 54 comprises a substantially U-shaped member, which partly surrounds the head 10 of the rotor and fits in the cylindrical cavity of the stator housing. The head portion 54 comprises a rotor axial stop shoulder 60, which rotor axial stop shoulder 60 extends above the edge 61 of the rotor head 10, so as to ensure that the rotor 6 cannot move out of the stator 4. The head portion 54 also provides a stable and secure anchoring of the starting actuator 30 to the stator housing.

The hinge 41 of the releasable locking mechanism 32 may be in the form of an integrally moulded web connecting the button 35 of the locking mechanism to the remainder of the priming actuator 30. To move the rotor 6 from the operating position to the starting position, the latch button 35 can be pressed by the user and simultaneously pushed in the starting direction P +, so that the starting actuator 30 is unlocked and axially displaced from the operating position to the starting position.

In the illustrated embodiment, the cam track 46 on the rotor head is disposed at an inner radial position about the periphery of the rim 50, the outer portion of the rim 50 being for engagement with the actuating shoulder 40 of the starter actuator 30. Since the cam track 46 defines a varying axial profile depending on the angular position of the rotor, an axial displacement of the rotor 6 relative to the stator 4 is produced by the cam track 46 pressing on the cam follower 48.

An external axial control shoulder 58 may be provided on the actuating edge 50 for ensuring that the rotor 6 is in the correct axial working position before the pump module is operating normally. In this regard, the starting actuator 30 is provided with an axial control shoulder 56 which allows the rotor to rotate in its operating position, but which axial control shoulder 56 engages the rotor head rim outer axial shoulder 58 if the rotor head rim outer axial shoulder 58 is in the wrong axial position in which the cam track 46 is not biased against the cam follower 48.

According to a variant of the invention (not shown), when the pump is in use, the rotor can be provided in the starting position before the first use and can be moved into the locked operating position after starting or without starting. In this variant, the locking mechanism for the rotor may be reversible or irreversible. In a variant with an irreversible locking mechanism, after the rotor has been moved from the start position to the operating position, it can no longer be released from the operating position. Various irreversible locking latches and locking systems can be implemented to achieve the one-way locking function.

List of illustrated features

Micro pump

Pump module 2

Stator 4

Inlet 14

An outlet 16

Complementary locking mechanism 33

Locking shoulder 37

Actuator stop 39

Complementary guide rail 52b

Starting actuator 30

Guide rail 52a

Head 54

Rotor axial stop shoulder 60

Rim axial control shoulder 56

Locking mechanism 32

Push button latch (pivotable) 34

Locking shoulder 36

Hinge 41

Stop 38

Actuating shoulder 40

First valve V1

First valve seal 18

Second valve V2

Second valve seal 20

Pump chamber seal 22

Rotor 6

Connection interface 7

Rotor head 10

Actuating edge 50

External axial shoulder 58

Internal axial shoulder 57

Cam track 46

Rotor shaft 12

First extension 24 (having a first diameter)

First passage 42

Recess 54

Second extension 26 (having a second diameter)

Second passage 44

End 45 (connected to the first extension)

Pump chamber 8 (formed between rotor and stator)

Axial displacement system

Cam system

Cam track 46 on the rotor

Complementary cam followers 48 on the stator

Rotary drive