Sample vials are used for collecting multiple specimens of analytes for analysis. For example, on a dairy farm, the milk of each animal may be sampled frequently and the samples sent to a laboratory to analyze them for fat content, impurities, any indications of disease, or other properties. The sample vials are then often discarded, so a large demand exists for inexpensive sample vials.
Certain sample vials commonly used for collecting milk specimens have previously been generally tubular with a round cross-section from bottom to top, a flat or concave bottom allowing the vials to stand up on a flat, level surface, and an integral lid joined to the body by an integral hinge. The sample vials have been carried in racks, resembling a common test tube rack, having wells that each receive a vial but do not latch the vial in place.
One piece liquid-tight vials are discussed in U.S. Pat. Nos. 4,783,056; 4,812,116; RE 37,676; and 6,303,064.
One aspect of the present disclosure is a sample vial. The vial has a generally tubular body. The vial has a generally round lip defining an opening at the top of the body. The vial has an asymmetric foot at the base of the body, the asymmetric foot having asymmetric first and second sides. Another aspect of the present disclosure is a rack for supporting a sample vial having an asymmetric foot and a projecting abutment. The rack supports the sample vial in a generally upright position in a single orientation. The rack has an asymmetric recess adapted to receive the asymmetric foot in a single orientation. The rack also has an orientation abutment adapted to interfere with a projecting abutment of a vial to prevent insertion of a vial into the asymmetric recess in an orientation other than the single orientation. The orientation abutment also allows insertion of a vial into the asymmetric recess in the single orientation.
Another aspect of the present disclosure is an assembly of a vial and a vial rack.
The vial of the assembly has a vial body and an asymmetric foot at the base of the vial body. The vial also has a downward-projecting vial abutment generally at the base of the body.
The rack of the assembly includes a rack body and an asymmetric recess in the rack body adapted to receive the asymmetric foot in a single orientation. The rack also has an orientation abutment adapted to interfere with a downward-projecting vial abutment to prevent insertion of the vial into the asymmetric recess in an orientation other than a single orientation. The orientation abutment allows insertion of a vial into the asymmetric recess in the single orientation. Optionally, the vial of any embodiment can have a liquid tight seal between the lid and the vial body. The liquid tight properties of the seal can be retained during multiple lid opening and closing. The generally round shape at the top of the vial body is well suited to obtain a liquid tight seal. Optionally, the asymmetric foot of any embodiment can have a bottom shaped to prevent the vial from standing upright when placed on a flat, level surface. Optionally, the bottom of the asymmetric foot can be convex.
Optionally, the vial of any embodiment can have a lid engageable with its lip to close the opening.
Optionally, the vial of any embodiment can have a tether connecting the lid to the body.
Optionally, the vial of any embodiment can have an integral hinge connecting the lid to the body.
Optionally, the asymmetric foot of any embodiment of the vial can be generally egg-shaped.
Optionally, the asymmetric foot of any embodiment of the vial can be configured to be received in a single orientation in a well of corresponding shape in a rack.
Optionally, the vial of any embodiment can have a lid engageable with its lip to close the opening.
Optionally, the vial of any embodiment can have a generally upward-facing abutment in the body.
Optionally, the vial of any embodiment can have a generally outward-projecting abutment generally at the base of the body.
Optionally, the vial of any embodiment can have a generally downward-projecting abutment generally at the base of the body.
Optionally, the tubular body of any embodiment can generally smoothly transition between a round lip and an asymmetric foot.
Optionally, the rack of any embodiment can have an inwardly-projecting latching abutment resiliently mounted adjacent to the recess and positioned to latch to an abutment of a vial inserted in the recess to secure the vial in the rack.
Optionally, the rack of any embodiment can have first and second inwardly-projecting latching abutments, each resiliently mounted adjacent to the recess and positioned to latch to an abutment of a vial inserted in the recess to secure the vial in the rack.
Optionally, the orientation abutment of any embodiment can be an upwardly-projecting abutment mounted adjacent to the recess.
Optionally, the orientation abutment of any embodiment can be an inwardly-projecting latching abutment resiliently mounted adjacent to the recess and positioned to latch to an abutment of a vial inserted in the recess to secure the vial in the rack.
Optionally, the rack of any embodiment can have multiple asymmetric recesses, each adapted to receive an asymmetric foot of a vial in a single orientation.
Optionally, the asymmetric foot of any embodiment can be positioned in the single orientation further into one of the asymmetric recesses than an asymmetric foot not positioned in the single orientation.
The following reference characters are used in the Figures.
The Figures show one embodiment of the invention.
In
Referring now to
In one embodiment, a liquid-tight and resealable vial such as 24 and lid such as 30 assembly is provided. The term “resealable” means that the vial can be opened/reopened and closed/reclosed several times (e.g. more than 5 times) and still retain its liquid-tight properties. The term “liquid-tight” means that the vial such as 24 passes a blue crystal dye test. The blue crystal dye test is a visual test to detect leaks within a vial seal. A vial such as 24 “passes” the blue crystal dye test if the white paper, in which the vial such as 24 is placed on, does not visually change color (i.e. the white paper does not become contaminated with the blue crystal dye liquid from the vial such as 24).
The blue crystal dye test procedure consists of the following: (a) the blue crystal dye liquid is prepared by adding one teaspoon of blue crystal dye powder to one gallon of alcohol and thoroughly mixing the solution; (b) the blue crystal dye liquid is poured into the vial such as 24 (i.e. a sufficient amount of the dye liquid must be added so, when the vial such as 24 is placed upside down, the entire seal area must be covered); (c) the lid such as 30 is fully closed on to the vial body; (d) the vial such as 24 is placed upside down (i.e. inverted) on the white paper at room temperature; and (e) after 30 minutes, the white paper is inspected to determine if the white paper is contaminated with the blue crystal dye liquid.
The asymmetric foot 38 has a bottom 44 shaped to prevent the sample vial 24 from standing upright when placed on a flat, level surface. As illustrated, the bottom 44 of the asymmetric foot 38 is convex. Alternatively, other shapes, such as pyramidal, a flat surface with a projecting part, a slanted surface, or other configurations can be used, or the sample vial 24 could have a bottom allowing it to stand upright in an alternative embodiment.
Referring specifically to
The sample vial 24 as illustrated has a generally outward-projecting and/or downward-projecting abutment 46, which can be a key or key tab, for example. In this embodiment, the abutment 46 is generally at the base of the body 32, and projects both outward and downward from the body 32. The downward and outward projection of the abutment 46 from the body 32 is best seen in
In the Figures, the tubular body 32 has a generally smoothly transition between the round lip 34 and the asymmetric foot 38. A more abrupt transition can alternatively be provided.
Referring now to
The recess 50 is defined by a front wall 52, a back wall 54, side walls 56 and 58, a floor 60, a collar 62, a shorter front latching tab 64, and a longer back latching tab 66. The latching tabs may alternatively be known as snap tabs, snap ribs, snap springs, or snap rings. The recess 50 as illustrated has side guides 68 and 70, longer front guides 72 and 74, and shorter back guides 76 and 78. As will be apparent, the rack 28 and its recesses such as 50 are skeletonized to a large degree to save on weight and material and to allow fluids to drain readily from the rack 28.
Plural abutments can be differentiated, as by making one stand taller than another with respect to the recess, to assist with orientation of the sample vial 24 in the recess. For example,
The rack 28 supports the sample vial 24 in a generally upright position in a single orientation in the recess 50. The orientation feature of the rack 28 allows the asymmetric foot 38 to be positioned further into one of the asymmetric recesses, when oriented in the intended single orientation, than an asymmetric foot 38 not oriented in the single orientation.
There is only one way to successfully insert the asymmetric foot 38 into the recess 50, or at least fully into the recess 50. As a result, if in this embodiment a sample vial 24 is not oriented correctly, it will stand in the rack 28 at a different height than the vials that are correctly inserted, providing a visual cue that one of the vials is not inserted correctly. This is illustrated in
Several features of the vials such as 24 and the rack 28 optionally contribute to this orientation functionality, either independently or in combination with other features. One feature contributing to the ability to distinguish an incorrectly oriented sample vial such as 86, shown particularly in
Another feature contributing to the detection of improper sample vial orientation is the different heights of the front and back latching tabs 64 and 66. The taller back latching tab 66, with its upward-projecting abutment 80, stops the advance of the downward-facing abutment 46 at a higher elevation than it otherwise would.
Another feature contributing to the detection of an improper sample vial orientation is provided by the arrangement of the guides 72-78 relative to the dimensions of the vial such as 24. This is illustrated by comparing
If the orientation of the sample vial 24 were reversed by rotating it 180 degrees about a vertical axis, “long” would confront “long” and “short” would confront “short.” Specifically, the guide 74 and the bearing point 96 would abut, and the guide 72 and the bearing point 98 would abut, and so forth. This would displace the downward facing abutment 46 outward over, and thus into interference with, the upward-projecting abutment 80, as shown in
The rack 28 of the assembly thus includes an asymmetric recess or base support structure in the rack body adapted to receive or support the asymmetric foot 38 in a single orientation. The rack 28 also has an upward-projecting abutment 80 adapted to interfere with the downward-projecting vial abutment 46 to prevent insertion of the sample vial 24 into the asymmetric recess 50 in an orientation other than a single orientation. The upward-projecting abutment 80 allows insertion of a sample vial 24 into the asymmetric recess in the single orientation.
Optionally, the rack 28 can have a fixture 106, such as an RFID ring, adapted for receiving a radio frequency identification (RFID) tag, so the rack 28 can be labeled. Optionally, the individual sample vials such as 22, 24, and 26 of the rack 28 can be identified by their positions in the rack 28. For example, the fixture 106 can be on one end of the rack 28, and the other end of the rack 28 can be provided with a recess 108 to receive the bracket or fixture of an adjacent, butted rack so the pitch between adjacent sample vials such as 24 and 26 in a rack 28, and the pitch between the last sample vial 24 of one rack 28 and the first sample vial 24 of another rack butted against the first one are all constant. A constant pitch may be useful to facilitate stepping a row of butted racks by a distance equal to the pitch to sequentially perform operations on the vials such as automated vial opening, sample removal, or vial closing, as may be performed on an automated analysis machine in certain embodiments.
Optionally, the rack 28 can have cut-outs such as 110 in the front and/or back walls 52 and 54 of each recess 50 to facilitate reading the labels of sample vials such as 24 carried in the rack 28. A fill line 112 can be provided.
Another aspect of the present disclosure is an assembly of a vial such as 24 and a vial rack 28, each as described.
Certain embodiments of the invention have been described in detail in this specification and illustrated by the drawing figures. This invention is not limited, however, to the specific embodiments and features described in the specification. The invention extends to the full scope of the claims as initially or later presented in this specification.
Priority is claimed to U.S. Ser. No. 61/059,398, filed Jun. 6, 2008. The foregoing application is incorporated by reference in its entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US09/46366 | 6/5/2009 | WO | 00 | 1/19/2011 |
Number | Date | Country | |
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61059398 | Jun 2008 | US |