The present invention relates to the field of multichannel pipetting systems such as automated pipetting systems called robots, and single-channel or multichannel sampling pipettes, also called laboratory pipettes, or air displacement liquid transfer pipettes, intended for the calibrated sampling and introduction of liquid into containers. Such pipettes, whether they are manual, motorised or hybrid, are intended to be held by hand by an operator during sampling and liquid dispensing operations.
The invention relates more specifically to the design of the tips of these pipetting systems, the tips being intended to carry the sampling cones forming consumable elements.
From the prior art, multichannel sampling pipettes are known, having a design of type integrating a body forming a handle, as well as a lower end having, at the end thereof, several sampling cone-carrying tips, of which the known function is to carry sampling cones, also called consumables.
On conventional pipettes, each tip comprises two annular portions for holding the cone, each forming a protrusion over the outer surface of the tip, and being spaced from one another along an axial direction of the tip. The upper holding portion, in protrusion form, mainly fulfils the function of holding the cone by friction, and limits the introduction in the latter, in the tip. The lower portion, although also contributing to holding the cone, fulfils the sealing function between the sampling cone and the tip. Together, the two holding portions ensure the centring of the tip and of the cone.
This design is the design that has been encountered for decades in pipettes.
However, a new design has recently been proposed, aiming to reinforce the ergonomics of the operation of press-fitting the cones. This design is defined in document FR 3 026 658. It provides a lip seal on the tip to ensure sealing with the sampling cone, as well as two portions for holding the cone arranged on either side of the seal. Because of this, the contact force between the cone and the tip at the level of two holding portions can be weak, since these portions are no longer used to obtain the sealing. The press-fitting force of the cones finds itself advantageously reduced, and slightly impacted by the cooperation between the cone and the lip seal, because of the intrinsic flexibility of the latter. For information purposes, with such a design, an axial press-fitting force of around 5 N through the tip proves to be sufficient for obtaining a sealing and a correct holding of each multichannel pipette cone. For example, sufficient results are obtained with an axial press-fitting force of around 40 N, on a multichannel, eight-tip pipette.
The operation of press-fitting the cones is thus more ergonomic, limiting the risks of musculoskeletal disorders (MSDs) for operators.
Thus, this design has the particularity of separating the tip means dedicated to the mechanical holding of the cone by friction, and those dedicated to obtaining sealing, formed by a lip seal, of which the bending force of the lip(s) is substantially less than the compression force of a conventional O-ring.
In addition, by axially offsetting the two holding portions, these ensure a long centring which moreover ensures a perfect lateral holding of the sampling cone, capable of resisting the radial stresses likely to be encountered during the handling of the pipette, during pipetting operations. Finally, the action of interleaving the seal between these two protruding holding portions, in other words, forming a relief on the outer surface of the tip, provides an optimisation of the axial length of the tip.
In view of the above, it is noted that the solution from document FR 3 026 658 gives a response to the need to reduce the press-fitting force/ejection force, while guaranteeing the sealing and the mechanical strength of the cones, even when the latter are stressed. Such a mechanical stress is produced, for example, during a “licking” movement carried out by the operator, during which the ends of the cones scrape the inner surface of a shaft in order to transfer the last drop of liquid likely to be retained by capillarity at the end of the consumable. In this scenario, it is important to preserve the mechanical strength of each cone, in order, in particular, to make them remain parallel to one another during the scraping on the successive shafts.
It is moreover noted, that to encourage the radial deformation of the collar of the sampling cone without increasing the press-fitting force, the annular holding portions can be made using specific elements spaced from one another, as is also mentioned in document FR 3 026 658. Therefore, a technique is related to, which enables to reinforce the mechanical strength of the cone, without increasing the press-fitting force.
Generally, the solution from document FR 3 026 658 is based on the presence of a seal arranged between two zones for holding/mechanically retaining the sampling cone, which can be applied to a single-channel pipette, even if it has a specific interest for multichannel pipettes.
In any case, there remains a need to optimise pipette tips, aiming to benefit from the advantages mentioned above, while expanding the compatibility of the tip with different types of consumables, in particular with different collar conicities encountered on sampling cones available on the market. In addition, this need exists similarly for robots, also intended to function with consumables of different shapes.
To at least partially meet this need, the invention first aims for a sampling cone-carrying tip for the lower end of a pipetting system, the tip having a longitudinal axis falling into a first fictitious plane.
According to the invention, the tip comprises successively from bottom to top along the longitudinal axis thereof, protruding radially towards the outside from an outer surface of the tip:
In addition, the tip also carries a gasket arranged between the first and the third annular zone of the tip.
Finally, on the one hand, the first maximum outer diameter as well as the second maximum outer diameter are different so as to together define a first tip portion having a first conicity, and on the other hand, the second maximum outer diameter as well as the third maximum outer diameter are different so as to together define a second tip portion having a second conicity, less than the first conicity.
The invention is noteworthy, in that it enables to define two tip portions which succeed one another axially and which therefore have different conicities, which could be adapted to a great variety of sampling cones. According to the geometry thereof, the cone will therefore be retained by friction by the first and second groups of retaining elements, or by the second and third groups of retaining elements, while cooperating with the seal to ensure sealing. In any case, the double mechanical retaining of the cone, by friction, ensures a satisfactory holding of the latter, in particular during a “licking” movement carried out by the operator.
Thanks to the invention, the range of using such tips is broadly extended, with no compromise on the holding, alignment and sealing of the sampling cones, nor on the intensity of the press-fitting force to be produced during coupling between the tip and the cone.
The invention also aims for a lower end of the pipetting system comprising at least one such sampling cone-carrying tip.
This lower end can be intended for a single-channel pipetting system, and thus comprise one single sampling cone-carrying tip.
Alternatively and preferably, the lower end of the pipette is intended for a multichannel pipetting system, and comprises a plurality of sampling cone-carrying tips having longitudinal axes falling into said first fictitious plane.
The invention has at least one of the following optional characteristics, taken by themselves, or in combination.
The first retaining elements of the first group, except for said two first retaining elements defining the first maximum outer diameter are situated radially towards the inside and remotely from a first fictitious circle defined by said first maximum outer diameter. This non-axisymmetric design enables to deform the collar of a non-circular cone using the two first retaining elements defining the first maximum outer diameter. An even more increased extension of the range of using the tip advantageously arises from this.
In this scenario, it is, for example, made sure that in addition to said two first retaining elements defining the first maximum outer diameter, one or more couples of first retaining elements defining one or more of the first diameters less than the first maximum outer diameter, among which at least one first smaller diameter situated in said first fictitious plane. This enables a substantially elliptic deformation of the collar of a cone, for an increase in the range of using the tip which is thus capable of being adapted to collars of varied conicities.
Similarly, the third retaining elements of the third group, except for said two third retaining elements defining the third maximum outer diameter, are situated radially towards the inside and remotely from a third fictitious circle defined by said third maximum outer diameter. Here also, it is preferably provided, that the third group comprises, in addition to said two third retaining elements defining the third maximum outer diameter, one or more couples of third retaining elements defining one or more third diameters less than the third maximum outer diameter, among which at least one third smaller diameter situated in said first fictitious plane.
Preferably, the second retaining elements of the second group are situated on a second fictitious circle defined by said second maximum outer diameter. However, a non-axisymmetric solution such as that defined above for the first and third groups could be adopted for the second group, without moving away from the scope of the invention.
However, in the axisymmetric solution, it is preferably made such that the second group comprises, in addition to said two second retaining elements defining the second maximum outer diameter, one or more couples of second retaining elements defining one or more other second maximum outer diameters, among which at least one second maximum outer diameter situated in said first fictitious plane.
Preferably, the first conicity is between 3 and 4.5°, and in that the second conicity is between 2 and 3.4°.
Preferably, for a multichannel pipetting system, the number of tips is between 2 and 16, and more preferably still, between 8 and 12.
To limit the press-fitting force, the gasket is preferably a lip seal. However, it could be an O-ring, without moving away from the scope of the invention.
The invention also aims for a pipetting system comprising a lower end such as defined above, said pipetting system being a manual sampling pipette, motorised, or hybrid, or this system being an automated pipetting system, called a robot.
Finally, the invention is based on an assembly comprising such a pipetting system, as well as at least one sampling cone mounted on the tip and retained on it by friction with the first and second retaining elements, or with the second and third retaining elements.
Other advantages and characteristics of the invention will appear in the non-limiting detailed description below.
This description will be made regarding the appended drawings, among which;
In reference firstly to
The air displacement pipette 1, manual or motorised, comprises, in the upper part, a body forming a handle 2, as well as a lower end 4, also subject of the present invention, integrating at the lower end thereof, pipette sampling cone-carrying tips 6, on which the cones of consumables 8 are intended to be press-fitted. Each cone 8 and the associated tip thereof form an assembly, also specific to the present invention.
The sampling cone-carrying tips 6 are spaced from one another along a lateral direction of the pipetting system, or again pipette lateral direction, represented by the arrow 10. Each tip 6 has a longitudinal axis 7, also called central axis, orthogonal to the direction 10. All longitudinal axes 7 are parallel and fall into a first fictitious plane P1, parallel to the direction 10. Furthermore, a second fictitious plane P2 has been represented in
Subsequently, it will be considered that at each tip 6, are associated a first fictitious plane P1 and a second fictitious plane P2, being intercepted at the level of the longitudinal axis 7 of the tip in question. In the plane P2, a direction 15 is also related, for moving the pipette by the operator during a movement called “licking”, during which the pipette is gradually moved above the successive lines of shafts of a plate, to dispense here the liquid sampled beforehand in the pipette. In this regard, it is noted that the number of tips 6 is preferably between 8 and 12, and that the plate used equally has rows of shafts, as well as a number of lines adapted, for example, to reach 384 shafts.
Each tip 6 has a through bore 12 communicating at the upper end thereof with a suction chamber (cannot be seen in
As is known to a person skilled in the art, the lower end 4 is preferably mounted screwed on the body 2 forming a handle. In a known manner, the lower end 4 comprises a fixed body 16 covered by a removable outer cap 17, and, at the low end thereof, the tips 6. The mobile inner parts of this lower end 4 are conventional, and will not be defined further. They relate, in particular, to a plurality of pistons parallel to the axis 14 and each associated with a tip 6.
One of the particularities of the invention resides in the design of the lower end 4, and in particular, of the tips 6 thereof, one of which will now be detailed in
The tip 6, at the low end thereof, has an outer surface 20 of overall cylindrical or truncated shape, getting narrower towards the bottom.
Generally, the tip is equipped with four zones for cooperating with the cones that it is likely to receive, these zones being spaced from one another along the longitudinal axis 7.
It firstly relates to three groups of elements for retaining the sampling cones by friction. The lowest group is the first group, comprising the first retaining elements, arranged protruding radially towards the outside from a first zone 20-1 of the surface 20, and spaced circumferentially from one another. Here, it relates to four first retaining elements, among which two first retaining elements 24-1a are arranged in the second fictitious plane P2, and defining a larger outer diameter, called first maximum outer diameter Dmax1. This diameter Dmax1 defines a first fictitious circle C1 centred on the axis 7 and inside which are contained two other first retaining elements 24-1b, radially remote from this same circle. The two elements 24-1b together form a couple which defines a first lower diameter Dinf1 of smaller size than that of the diameter Dmax1. This diameter Dinf1 is orthogonal to the diameter Dmax1, and situated in the first fictitious plane P1.
It is indicated that on the figures, the retaining elements have been voluntarily enlarged for reasons of clarity. In reality, there are simple reliefs having a low height h of around 0.2 to 0.7 mm, this height h corresponding to the protruding distance from the outer surface 20.
Then, a second group comprising second retaining elements arranged radially protruding towards the outside from a second zone 20-2 of the surface 20 is provided, and spaced circumferentially from one another. Here, it relates to four second retaining elements, among which two second retaining elements 24-2a are arranged in the second fictitious plane P2, and defining a larger outer diameter, called second maximum outer diameter Dmax2. This diameter Dmax2 defines a second fictitious circle C2 centred on the axis 7 and on which is also located, two other second retaining elements 24-2a. These two other elements together form a couple which defines another second maximum outer diameter Dmax2, situated in the first fictitious plane P1. Thus, the two maximum outer diameters Dmax2 are of the same size, and, more generally, all the second retaining elements 24-2a fall into the same second fictitious circle C2.
The highest group on the tip is the third group, comprising the third retaining elements, arranged radially protruding towards the outside, from a third zone 20-3 of the surface 20, and spaced circumferentially from one another. Here, it relates to four third retaining elements, among which two third retaining elements 24-3a are arranged in the second fictitious plane P2, and defining a larger outer diameter, called third maximum outer diameter Dmax3. This diameter Dmax3 defines a third fictitious circle C3 centred on the axis 7 and inside which are contained two other third retaining elements 24-3b, radially remote from this same circle. The two elements 24-3b together form a couple which defines a third lower diameter Dinf3 of smaller size than that of the diameter Dmax3. This diameter Dinf3 is orthogonal to the diameter Dmax3, and situated in the first fictitious plane P1.
Moreover, the fourth zone for cooperating with the cone is constituted by an annular gasket 26, housed in a recess 28 of the outer surface 20 of the tip. It preferably relates to a lip seal 26 to decrease the press-fitting force, this seal being situated between the first group and the second group. Alternatively, the seal 26 could be arranged between the second group and the third group, without moving away from scope of the invention.
The lip seal 26 has one or more lips, preferably one single lip. The lip is of a truncated shape, flaring towards the top, from an annular base of the seal. The annular base and the lip are preferably made from one single part, from EPDM-type elastomer material, while having a Shore A hardness of 40 to 100.
In a non-constrained state, the lip seal 26 has an outer diameter, for example, of around 4 mm.
The first maximum outer diameter Dmax1 is less than the second maximum outer diameter Dmax2. Together, they define, thanks to the difference in size thereof, a first longitudinal portion of tip 6a centred on the axis 7 and having a first conicity, schematised by the line referenced Con1 in
As an example, the first conicity Con1 is between 3 and 4.5°, whereas the second conicity Con2 is between 2 and 3.4°.
Thus, according to the conicity of the collar 8a of the cone to be press-fitted, the latter will have the inner surface thereof held by friction, either by the first and the second group of retaining elements, or by the second and third groups of retaining elements. In any case, the retention by friction will be achieved using two groups, axially spaced from one another, for a satisfactory mechanical holding, and for the preservation of the centring and of the parallelism between the cones present on the different tips of the multichannel pipette.
The sealing itself represents a function fulfilled separately, by the dedicated seal 26.
Now, in reference to
In another example shown in
Now, in reference to
In another example shown in
Of course, various modifications can be made by a person skilled in the art to the invention which has just been defined, only as non-limiting examples. In particular, the invention is identically or similarly applied to a tip of an automated pipetting system, also called a robot.
Number | Date | Country | Kind |
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16 55652 | Jun 2016 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2017/051552 | 6/15/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/216489 | 12/21/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
20100196210 | Jungheim | Aug 2010 | A1 |
20110174087 | Kimura | Jul 2011 | A1 |
20170028397 | Dudek | Feb 2017 | A1 |
20180178211 | Dudek et al. | Jun 2018 | A1 |
20180250667 | Dudek | Sep 2018 | A1 |
Number | Date | Country |
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3026658 | Apr 2016 | FR |
3026658 | Apr 2016 | FR |
Entry |
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International Search Report for International Application Serial No. PCT/FR2017/051552 dated Aug. 17, 2017. |
Preliminary French Search Report for French Patent Application Serial No. 1655652 dated Feb. 6, 2017. |
Number | Date | Country | |
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20190329239 A1 | Oct 2019 | US |