Not applicable.
Not applicable.
The present disclosure relates to the field of pipetting systems such as manual pipetting systems (e.g., single-channel or multichannel sampling pipettes, also referred to as laboratory pipettes, or even air-displacement liquid transfer pipettes) intended for the sampling and calibrated introduction of liquid into receptacles. These types of pipettes, whether they are manual, motorized, or a combination of the two, are intended to be held in the hand by an operator during the sampling and dispensing operations of liquid.
Conventional pipettes are provided with a sampling volume adjustment screw, which is controlled in rotation by a pipette control button, via a control shaft that connects the button to the volume adjustment screw. Pipettes of the types disclosed herein are very precise devices that require specific and fine-tuned tolerances during the manufacture thereof, which can increase time and costs to manufacture. Historically, such pipettes have been subject to minimal customization by an end user due to the difficulties of modifying various components for inclusion in multiple pipette systems.
When the pipette comprises a counter designed to display very precise volume values, for example a three-figure or four-figure counter, adjustment of the pipette to a given value may sometimes prove to be challenging. Sometimes, the last digit in four-figure counters are associated with a drum that can rotate faster than the pipette control button activated by the operator, hence the difficulty of obtaining the precise value desired. Thus, depending on the counter used in the pipette system, the interior parts of the pipette system may differ to address problems unique to each specific counter. Further, some pipette designs include an internal lever system to improve pipette tip ejection or include other interior adjustment parts that provide a variety of volume adjustment settings, such as free adjustment, fine adjustment, and locked.
The interior adjustment part dimensions can vary depending on the functional features included with a particular pipette, such as those noted above. In many instances, the housing is adapted to accept the different adjustment part dimensions, and therefore, conventional pipettes can have varying external geometries designed to accommodate the differences in internal configurations. As a result, in some prior art systems, inclusion of multiple functional features in a pipette may result in a larger housing being required to accommodate the features.
Therefore, in prior art systems, the design parameters for three-figure or four-figure counters are different and can lead to extra cost and waste for manufacturers by having to produce a number of different pipette housings to accommodate the counters and the associated components. The housing shape and size differences also create discontinuity of the exterior design and of other features contributing to ergonomic design benefits, which may lead to user discomfort or stress when switching between pipettes having different functional features.
To address this problem, it would be desirable to have a pipette system with a uniform housing that is designed to accommodate a variety of configurations of the pipette system to reduce manufacturing costs and to maintain a uniform look and feel for the end user.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is configured to receive one of a plurality of volume counters without modification of the housing, and the plurality of volume counters includes a first counter and a second counter different than the first counter.
In some embodiments, the pipette system includes a hook, and the hook extends away from a central axis of the housing at a radius of curvature configured to rest on an index finger of a user during use. The housing has a widest cross-section, and the widest cross-section of the housing can be between about 2.9 and about 3.2 times a length of the radius of curvature of the hook. The pipette system can include a control button coupled to a control shaft that extends away from a control end of the housing and the widest cross-section of the housing can be between about 0.9 and about 1.2 times a distance from the control end of the housing to a top of the control button. The pipette system can include an ejector coupled to the housing opposite the opening positioned in the front wall of the housing, and the widest cross-section of the housing can be between about 1.9 and about 2.1 times a distance from a central axis of the ejector to a central axis of the control button. In some embodiments, the distance from the control end of the housing to a top of the control button is between about 1.8 and about 2.4 times a distance from a central axis of the ejector to a central axis of the control button.
In some embodiments, the housing has a widest cross-section and the housing forms a hook, the hook extending away from a central axis of the housing at a radius of curvature. The pipette system can further include a control button coupled to a control shaft that extends away from a control end of the housing and an ejector coupled to the housing opposite the opening. The widest cross-section can be between 2 and 3 times a length of the radius of curvature of the hook. A distance from the control end of the housing to a top of the control button can be between 2 and 4 times the length of the radius of curvature of the hook, and a distance from a central axis of the ejector to a central axis of the control button can be between 1 and 2 times the length of the radius of curvature of the hook.
In some embodiments, the opening can be configured to receive and retain a plurality of window guides by an interference fit. The plurality of window guides can include a first window guide and a second window guide. The first window guide can have a hollow center that corresponds to a first in-use configuration and the second window guide can have a window and correspond to a second in-use configuration different than the first in-use configuration. The hollow center can at least partially reveal the first counter in the first in-use configuration and the window can at least partially reveal the second counter in the second in-use configuration.
In some embodiments, the first counter has a first number of digits and the second counter has a second number of digits different than the first number of digits. The first number of digits can be three and the second number of digits can be four, the first counter including an insertable spacer and the first counter designed to mechanically attach to the insertable spacer. The first counter can correspond to a first set of interior adjustment parts, the second counter can correspond to a second set of interior adjustment parts different than the first set of interior adjustment parts, and the interior space of the housing can have a size, shape, and volume to interchangeably retain the first set of interior adjustment parts or the second set of interior adjustment parts without modification of an exterior portion of the housing. The first counter can correspond to a first in use configuration and the second counter can correspond to a second in use configuration different than the first in use configuration.
In some embodiments, the body includes a lever. The lever can contact an ejector and the lever can be movably coupled to an interior adjustment part. The pipette system can include an adjustment feature controlled by a selector control button and is configured to provide a plurality of adjustment mechanisms. The selector control button can provide adjustment positions including one or more of a free adjustment position, a fine adjustment position, and a latched position.
According to one aspect, a body of a pipette system for transporting a measured volume of liquid is provided. The body includes a housing defining an interior space and an opening positioned on a front wall of the housing. The interior space can be dimensioned to receive a first volume counter having three-digits and a second volume counter having four-digits, without modification of the housing. The first counter can include an insertable spacer and the insertable spacer can be designed to mechanically attach to the first counter. The volume of the first counter and the spacer can be substantially equal to the volume of the second counter.
In some embodiments, a method of manufacturing a pipette system includes the steps of providing a housing that is configured to receive a first volume counter or a second volume counter, the first volume counter being different than the second volume counter, providing a first set of interior adjustment parts that is configured to be coupled with the first volume counter or providing a second set of interior adjustment parts that is configured to be coupled with the second volume counter, assembling the first set of interior adjustment parts or the second set of interior adjustment parts within the housing, and inserting the first volume counter or the second volume counter into a cavity defined by the housing.
In some embodiments, the method further includes the step of inserting a spacer into an interior space of the housing before inserting the first volume counter into the cavity. In some embodiments, the method further includes the step of providing an ejector system with the housing, the ejector system including an ejection lever. In some embodiments, the first set of interior adjustment parts are only configured to be coupled with the first volume counter, and the second set of interior adjustment parts are only configured to be coupled with the second volume counter. In some embodiments, the first volume counter has a first number of digits and the second volume counter has a second number of digits different than the first number of digits.
In some embodiments, the second volume counter is larger in size than the first volume counter. In some embodiments, the first set of interior adjustment parts are configured to be coupled with the first volume counter or with the second volume counter. In some embodiments, the housing interchangeably retains the first set of interior adjustment parts or the second set of interior adjustment parts without modification of an exterior of the housing. In some embodiments, the opening is configured to receive and retain a first window guide or a second window guide that is different than the first window guide. In some embodiments, the method further includes the step of providing a position selector that is displaced in rotation among at least three positions, and the position selector is one of the first or second interior adjustment parts.
According to a different aspect, a kit for assembling a pipette system includes a body including a housing defining an interior space, the body defining a housing with an elongate opening positioned in a front wall of the housing, a first volume counter configured to be inserted into the body or a second volume counter configured to be inserted into the body, and a first set of interior adjustment parts configured to be coupled with the first volume counter or a second set of interior adjustment parts configured to be coupled with the second volume counter. The opening is configured to receive the first volume counter into the interior space or the second volume counter into the interior space without modification of the housing.
In some embodiments, the first volume counter has a first number of digits and the second volume counter has a second number of digits different than the first number of digits. In some embodiments, the kit further includes a spacer configured to be coupled with the first volume counter. In some embodiments, the volume of the first volume counter and the spacer is substantially equal to the volume of the second volume counter. In some embodiments, each of the first volume counter and the second volume counter are configured to be inserted into the interior space of the body and adjacent the elongate opening without modification to the housing. In some embodiments, the kit further includes an ejector system with the housing, the ejector system being configured for coupling with the body. In some embodiments, the ejector system includes a lever. In some embodiments, the elongate opening is configured to receive and retain a first window guide or a second window guide that is different than the first window guide. In some embodiments, the kit further includes a position selector that is displaced in rotation among at least three positions, and the position selector is one of the first or second interior adjustment parts. In some embodiments, the housing includes a hook, the hook extending away from a central axis of the housing at a radius of curvature configured to rest on an index finger of a user during an in-use configuration.
According to a different aspect, a method of manufacturing and assembling a pipette system for transporting a measured volume of liquid is provided. The method can include the step of receiving a housing for a pipette system, the housing defining an interior space and a hook. The hook extends away from a central axis of the housing at a radius of curvature, and the interior space is dimensioned to receive a plurality of different volume counters having either three-digits or four-digits.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body having a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter.
According to another aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body having a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The rounded control button can include an electronic device configured to wirelessly transmit signals by wireless link.
According to a further aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system comprises a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system including a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button and is configured to provide a plurality of adjustment mechanisms.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system comprising a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, and is configured to provide a plurality of adjustment mechanisms
According to a different aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body having a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a control button coupled to a control shaft that extends away from a control end of the housing.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided, the pipette system is provided in the form of a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to another aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body having a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms.
According to a further aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system includes a body having a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a three-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system comprising a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The rounded control button can include an electronic device configured to wirelessly transmit signals by wireless link.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system has a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system comprising a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, and is configured to provide a plurality of adjustment mechanisms
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a control button coupled to a control shaft that extends away from a control end of the housing.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button, and is configured to provide a plurality of adjustment mechanisms.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes a four-digit counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The rounded control button can include an electronic device configured to wirelessly transmit signals by wireless link.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a rounded control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a control button coupled to a control shaft that extends away from a control end of the housing.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms.
According to one aspect, a pipette system for transporting a measured volume of liquid is provided. The pipette system having a body including a housing defining an interior space, and an elongate opening positioned in a front wall of the housing. The interior space is dimensioned to receive a plurality of volume counters, and the plurality of volume counters includes a first counter, a second counter different than the first counter, and a third counter different than the second counter and the first counter. The pipette system includes an electronic counter and a flat control button coupled to a control shaft that extends away from a control end of the housing. The pipette system includes an ejection system with an added assist, including a lever and an adjustment feature controlled by a selector control button, configured to provide a plurality of adjustment mechanisms.
Other aspects and advantages of the present disclosure will become apparent upon consideration of the following detailed description, wherein similar structures have similar reference numerals.
The following discussion is presented to enable a person skilled in the art to make and use embodiments of the disclosure. Various modifications to the illustrated embodiments will be readily apparent to those skilled in the art, and the generic principles herein can be applied to other embodiments and applications without departing from embodiments of the disclosure. Thus, embodiments of the disclosure are not intended to be limited to embodiments shown, but are to be accorded the widest scope consistent with the principles and features disclosed herein. The following detailed description is to be read with reference to the figures, in which like elements in different figures have like reference numerals. The figures, which are not necessarily to scale, depict selected embodiments and are not intended to limit the scope of embodiments of the disclosure. Skilled artisans will recognize the examples provided herein have many useful alternatives and fall within the scope of embodiments of the disclosure.
It is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. For example, the use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items.
As used herein, unless otherwise specified or limited, the terms “mounted,” “connected,” “supported,” “secured,” and “coupled” and variations thereof, as used with reference to physical connections, are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, unless otherwise specified or limited, “connected,” “attached,” or “coupled” are not restricted to physical or mechanical connections, attachments or couplings.
As used herein, unless otherwise specified or limited, “at least one of A, B, and C,” and similar other phrases, are meant to indicate A, or B, or C, or any combination of A, B, and/or C. As such, this phrase, and similar other phrases can include single or multiple instances of A, B, and/or C, and, in the case that any of A, B, and/or C indicates a category of elements, single or multiple instances of any of the elements of the categories A, B, and/or C.”
As discussed above, pipette systems can include a number of different functional features to aid in the measurement and transfer of liquid. For example, pipette systems can include a counter designed to alert the user as to how much liquid is being transferred. For example, in some instances, a three or a four-digit counter may be used depending on the desired reading accuracy of liquid transfer. In other instances, an electronic counter may be used and may include, for example, one or more of a microprocessor, brushes, a coder, liquid crystal screen and electronic circuit such as in the pipette described in U.S. Pat. No. 7,373,848, which is incorporated by reference herein in its entirety. Pipette systems may also include one or more of internal levers to lower the required pipette tip ejection force, or adjustable locking mechanisms to lock the transfer volume selected by the user. Because different pipette functionalities require different interior adjustment parts having unique dimensions and space requirements, it can be useful to provide a more universalized pipette body that is capable of accommodating many different combinations of interior adjustment part dimensions arising from different combinations of pipette functionalities. Further, by providing a universalized body design, users can rely on the continuity of ergonomic feel of the pipettes being used, regardless of the functionalities associated with a particular pipette. Also, manufactures can benefit from being able to assemble pipettes having different functionalities using one universalized pipette body. Embodiments described herein provide these and other benefits.
The pipette 1, shown here in its manual version, comprises in its upper part a body forming a handle 2, as well as a lower part 4 intended to include, at its lower end, a sampling cone-mounting tip (not shown). The tip is provided to accommodate a cone, which is disposable and is intended to be ejected from the end by an ejection system 6 once the pipetting operations have been completed.
As shown in
In a known manner, the rotation of the adjustment screw 14 causes translation along axis 12, or the translation of another piece, in order to axially displace a piston lodged in a suction chamber in the lower part 4 of the pipette. It is the adjustment of the upper position of the piston that makes it possible to affect the volume ultimately sampled in the pipetting process.
The counter 20 comprises a system of gears equipped with an exterior toothed wheel 22 centered on the axis 12, directly driven in rotation by the adjustment screw 14. The driving occurs, for example, through a lug projecting inwards starting from a wheel 22, and lodged in a longitudinal groove 24 of the screw 14. The wheel 22 gears with another eccentric wheel 26 with exterior teeth, which itself gears with a set of teeth provided on a fourth drum 28d of the counter 20, which gives information to the fourth adjusted volume figure. The fourth drum 28d (See
The counter 20 also comprises a first drum 28a, a second drum 28b, as well as a third drum 28c which respectively display the first, second, and third figures of adjusted volume. The drums 28a-28d are stacked along the axis 12, and drive each other in a known manner, through movement transmission devices 30. In applications where a three-digit counter is desired, the fourth drum 28d may be omitted and the three-digit counter 100 may include a transparent housing 198 (See
Referring to
The volume mode setting system 32 depicted in
Referring to
Referring back to
The spring 38 applies a pressure on the upper part of the first wheel 34, via a low spring end lodged in an upper recess of the wheel 34. The axial force developed by the spring 38 thus causes the first wheel 34 to shift downwards and to press itself against the second wheel 36 which remains fixed in translation, with, consequently, the first and second teeth 40, 46 being fitted together.
A preferred arrangement of the teeth is described with respect to
Referring to
In a similar manner, the second row 58b, corresponding to the interior row, is discontinuous. This implies that it is formed by toothed portions 60b each of which corresponds to an arc segment provided with the teeth 46. The toothed portions 60b are spaced circumferentially from each other, preferably in a regular manner. Between the toothed portions 60b, there are non-toothed portions 62b, corresponding to hollowed-out portions. As an example, the second annular row 58b consists of four toothed portions 60b of about ten teeth each, as well as four non-toothed portions 62b that present substantially the same angular span as the toothed portions 60b.
As illustrated in
Each recovery zone 64 is formed by a recovery sector 66a corresponding to one end of one of the toothed portions 60a, as well as by a recovery sector 66b corresponding to one end of one of the toothed portions 60b. The two sectors 66a, 66b are thus facing each other radially, to form one of the recovery zones 64 (e.g., eight zones), spaced regularly from each other. The number of teeth per sector 66a, 66b is for example between 2 and 5, and may be 2, 3, 4, or 5.
Within each recovery zone 64, the teeth 46 of the sector 66a are offset by a half-pitch P/2 relative to the teeth 46 of the sector 66b. Referring to
To do this, the radial length of each first tooth 40 is, for example, about twice as large as the radial length of each second tooth 46, which makes it possible to establish two contact surfaces 70a, 70b between a first tooth 40, and the two teeth 46 that are directly consecutive inside the recovery zone 64. In this regard, it should be noted that these surfaces 70a, 70b, which are visible at the bottom of
In operation, when the operator adjusts the desired volume using the control button 8, s/he drives the screw 14, which itself causes the simultaneous rotation of the second wheel 36. Adjusting the volume between its lower and upper boundaries habitually requires multiple turns of the control button. During the rotational motion of the second wheel 36, the second teeth 46 in motion exert a force on the first teeth 40, which tends to push the first wheel 34 axially upward, before the wheel 34 is once again forced to go back downward under the antagonistic effect of spring 38. This back-and-forth axial motion of the first wheel 34 is observed each time one tooth passes to another, and it makes it possible for the volume mode setting system 32 to index the screw 14 in a very high number of positions. This facilitates the execution of a precise adjustment of the desired volume. In particular, within each recovery zone 64, the number of possible positions for the same first tooth 40 relative to wheel 46, corresponds noticeably to double the number of second teeth 46 in each recovery sector 66a, 66b that forms each zone 64.
As an example, it can be noted that during one 360° rotation of the adjustment screw 14, it can be indexed in dozens of different angular positions, with each of these positions being stable and precise, due to the fit, at each different time, between the first and second teeth 40, 46. The precision of the volume adjustment is advantageously accrued, without altering the ease of manufacture of the toothed wheels 34, 36. The wheels 34, 36 can be produced by plastic injection, while preserving a satisfactory tooth quality.
With respect to
The exterior grip portion 84 is followed by an interior part 86 of the selector, made of a single block with the exterior grip portion 84. The interior part 86, which is lodged inside of the handle 2, surrounds a part of the spring 38. At its lower end, the interior part 86 fits into the other part of system 74, namely an annular control device 88 that surrounds the two toothed wheels 34, 36. The two parts 82, 88 are coupled to each other in rotation, through components 90 on an upper end of the control device 88, lodged in axial slots 92 on the low end of the selector 82. The two parts 82, 88 are designed to remain fixed in translation along the axis 12, while still being able to turn together about this same axis 12.
The control device 88 fits with the first toothed wheel 34, constituting the blockage wheel of the volume mode setting system 32. This fit occurs via the radial lugs 42, which radially cross the control device 88 so that their outer ends become lodged in a sliding manner in the longitudinal grooves 44 of the handle 2.
Each radial lug 42 is associated with a track of the control device 88, by being pressed up against this track via the spring 38 which acts on the toothed wheel 34 that bears these lugs. Four radial lugs 42 and four tracks are provided on the control device 88, as shown in
Referring to
Finally, a third portion of track 94c is provided to the right starting from the second portion of track 94b, the third portion 94c being located axially at the same level and in the continuity of the second portion 94b. A stop component 95 is arranged facing axially from the third track portion 94c, being borne by the control component 88. With this third track portion 94c, the stop component 95 forms a slot 96 that is circumferentially open from the side where the second portion 94b is located. On the opposite side, the slot 96 is closed by a slot bottom 97. Consequently, this configuration takes the shape of a hook that is circumferentially open in the direction of the second track portion 94b.
Subsequently, with respect to
Finally, referring to
The three positions are thus selected in an appropriate manner by the operator, depending on the desired adjustment. For example, the start of the adjustment may be carried out in the free adjustment position in order to effortlessly select from a wide range of volumes, then as the target value is approached, the fine adjustment position may be adopted in such manner as to easily attain this precise value. Once this value has been attained, the selector may then be placed in the latched position, in order to prevent any accidental change of the target volume, during the subsequent pipetting operations.
Finally, in addition to references 99, the operator is alerted about the passage of selector 82 to each of the three positions by audible clicks, which are obtained in the standard manner by shapes that fit between handle 2 and selector 82.
Of course, various modifications can be made to the disclosure. For example, within the volume mode setting system 32, modifications could be made to place the multiple annular rows on the first wheel, and not on the second toothed wheel 36, which would then present only a single annular row of teeth. Alternatively, the two toothed wheels could each feature a single annular row of teeth, without departing from the scope of the disclosure. As described above, various embodiments of the pipette 1 can include a number of functional features, such as a three or a four-digit counter, an electronic counter and/or a latching device 80. As provided the above description, depending on which functional features are included in the pipette 1, different interior adjustment parts are installed within the housing.
Referring now to
Referring to
The side wall 204 and the base 206 generally define a counter space 220 of a size and shape configured to receive and substantially surround the three-digit counter 100. The through-hole 202 is sized and shaped to receive a pin 222 extending from the bottom of the transparent housing 198 of the three-digit counter 100, and the protruding half-circle 210 is sized and shaped to receive the movement transmission devices 30. When the three-digit counter 100 is received within the counter space 220, the notches 218 extend into grooves 224 formed on the upper perimeter of the three-digit counter 100 and corresponding to the heads 216 so that the spacer 124 is mechanically coupled to the three-digit counter 100. As discussed herein, the interior space 126 of the housing 112 is designed to accommodate other sized counters. Additionally, the housing 112 forms a hook 132, which is shaped to receive the index finger of a user. The hook 132 extends away from the longitudinal central axis 12, forming an arc with a defined radius of curvature 134 (see
In some embodiments, the window guide feature of the pipette system 102 is designed to correspond with a particular size and number of counting digits of the counter implemented with the pipette system 102. For example, as shown in
Referring to
As illustrated in
As shown in
In some embodiments, if the pipette system 102 includes the control system 74 (shown in
To accommodate variations in the interior adjustment parts 110 corresponding to different functional features while also preserving a consistent exterior design 160 of the pipette system 102, the pipette body 104 can interchangeably receive various interior adjustment parts 110. In this way, regardless of the chosen functional features of the pipette system 102, the pipette system 102 provides the same feel, ease of use, and other ergonomic benefits for users.
Referring to
The widest cross-section 170 of the housing 112 can be between about 1 and about 4 times the radius of curvature 134 of the hook 132. The widest cross-section 170 of the housing 112 can be between about 2 and about 3 times the radius of curvature 134 of the hook 132. The widest cross-section 170 of the housing 112 can be between 2.9 and 3.2 times the radius of curvature 134 of the hook 132. Additionally, the button extension distance 164 can be between about 1 and about 4 times the length of the radius of curvature 134 when the pipette is adjusted to its nominal volume (e.g. the maximum volume). The button extension distance 164 can be between 2 and 4 times the length of the radius of curvature 134, when the pipette is adjusted to its nominal volume (e.g. the maximum volume). The button extension distance 164 can be between 2.7 and 3.6 times the length of the radius of curvature 134, when the pipette is adjusted to its nominal volume (e.g. the maximum volume).
A gripping distance 174 between the central axes 156, 158 can be between about 0.1 and about 3 times the length of the radius of curvature 134. The gripping distance 174 between the central axes 156, 158 can be between 1 and 2 times the length of the radius of curvature 134. The gripping distance 174 between the central axes 156, 158 can be between 1.4 and 1.6 times the length of the radius of curvature 134. The widest cross-section 170 can be between about 1 and about 2 times the button extension distance 164. The widest cross-section 170 can be between 0.9 and 1.2 times the button extension distance 164. The widest cross-section 170 of the housing 112 can be between about 1 and about 3 times the gripping distance 174 between central axes 156, 158. The widest cross-section 170 of the housing 112 can be between 1.9 and 2.1 times the gripping distance 174 between central axes 156, 158. The design dimensions and ratios are contemplated to improve ergonomic use of the pipette system 102, as well as retain the housing 112 dimensions in such a way to accommodate various components including, e.g., a three-digit counter 100, four-digit counter 20, or an electronic counter. The button extension distance 164 can be between about 1.8 and about 2.4 times the gripping distance 174 between central axes 156, 158. The button extension distance 164 can be between 1.8 and 2.4 times the gripping distance 174 between central axes 156, 158.
As further shown in
To achieve a substantially flat control button 119 as shown in
Some embodiments provide a method of manufacturing and assembling the pipette system disclosed herein. The method includes receiving a housing defining an interior space and a hook, the hook extending away from a central axis of the housing at a radius of curvature. Further, the interior space of the housing is dimensioned to receive a plurality of different volume counters, but only one counter at a time. A control button is provided and coupled to a control shaft and an ejector. The control button, ejector, and housing are assembled so that the control shaft extends away from a control end of the housing and the ejector is coupled to the body.
The control shaft, ejector and housing can also be assembled so that the widest cross-section of the housing is between about 1 and about 4 times the radius of curvature of the hook. The control shaft, ejector, and housing can also be assembled so that the widest cross-section of the housing is between 2 to 3 times the radius of curvature of the hook. The control shaft, ejector and housing can also be assembled so that the widest cross-section of the housing is between 2.9 to 3.2 times the radius of curvature of the hook. Additionally, a distance from the control end of the housing to a top of the control button, when the pipette is adjusted to its nominal volume (e.g. the maximum volume), is between about 1 and about 4, 2 to 4, or 2.7 to 3.6 times the length of the radius of curvature of the hook. A distance from a central axis of the ejector to a central axis of the control button is between about 0.1 and about 3, or between about 1 and about 2, or between about 1.4 and about 1.6 times the length of the radius of curvature. The widest cross-section of the housing can be between about 1 and about 3 times the gripping distance 174 between central axes. The widest cross-section of the housing can be between about 1.9 and about 2.1 times the gripping distance 174 between central axes.
A number of different volume counters can be installed into the housing, such as a three-digit counter, a four-digit counter, or an electronic counter. More specifically, for at least one type of in-use configuration, a three-digit counter is installed, and for another type of in-use configuration, a four-digit counter is installed. A further in-use configuration is provided in the form of the pipette system having an electronic counter. A spacer having a substantially cylindrical side wall and a base can form a counter space sized and shaped to receive a three-digit counter. The method of assembling the pipette system can include the step of inserting the three-digit counter into the counter space of the spacer to mechanically couple the spacer to the three-digit counter. The combination of the three-digit counter and the spacer can then be inserted through an opening in the housing into the interior space, and secured in the housing by coupling a window guide.
In some embodiments, the pipette system 102 may be provided in the form of a kit during manufacturing, which may include one or more of the components listed above. In particular, in addition to the body 104, a kit for assembling the pipette system 102 may include the three-digit counter 100, the spacer 124, and the window guide 122. In some embodiments, the kit may include the four-digit counter 20 and a partially transparent window 144. In some embodiments, the kit may include the three-digit counter 100, the spacer 124, the window guide 122, and the position selector 82 that is displaced in rotation according to the axis 12 among three positions. In some embodiments, the kit may include the four-digit counter 20 and the position selector 82.
In some embodiments, a four-digit counter can be inserted into the housing rather than the three-digit counter. The four-digit counter, similarly, is inserted into the opening in the housing, and is received into the interior space. A window guide, which has a window sized to display the numbering of a four-digit counter is then coupled to the housing by way of the opening to secure the four-digit counter into the interior space.
In this way, a single pipette housing can be made in a manufacturing process. The pipette housing can then receive either the three-digit counter and its associated components, the four-digit counter and its components, or the electronic counter and its associated components.
Any of the embodiments described herein may be modified to include any of the structures or methodologies disclosed in connection with different embodiments. Further, the present disclosure is not limited to air-displacement or positive displacement pipettes of the type specifically shown.
Numerous modifications to the present disclosure will be apparent to those skilled in the art in view of the foregoing description. Accordingly, this description is to be construed as illustrative only and is presented for the purpose of enabling those skilled in the art to make and use the disclosure and to teach the best mode of carrying out same. The exclusive rights to all modifications which come within the scope of the appended claims are reserved.
This application claims the benefit of U.S. Patent Application No. 62/847,720, filed on May 14, 2019, and entitled “PIPETTE SYSTEM WITH INTERCHANGEABLE VOLUME COUNTER,” the entire contents of which is incorporated by reference herein in its entirety.
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Number | Date | Country | |
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