WO2022096307A1 - Tube conveyor capsule for the transport of test tubes - Google Patents

Abstract

The invention relates to a tube conveyor capsule (10) for the transportation of test tubes (12) for bodily fluids along a pneumatic tube conveyor system, comprising • a tubular main body (14), which at both ends has an opening (16) which can be closed in each case with a lid (18), • a receptacle (26), which is arranged inside the main body (14) and into which a plurality of test tubes (12) can be inserted next to each other and one behind the other in the direction of the longitudinal axis of the main body (14); and • a holding device (28) with a plurality of resiliently deformable holding fingers (30), which are each arranged running obliquely with respect to the longitudinal axis L and which each project into the receptacle (26) in such a manner that each test tube (12) inserted into the receptacle (26) is held clamped between a plurality of the holding fingers (30); wherein • the holding fingers (30) or the holding device (28) consist(s) of an elastomer or of rubber; wherein • the receptacle (26) has a polygonal, in particular rectangular, cross-sectional shape and the holding fingers (30) protrude into the receptacle (26) from two mutually opposing sidewalls (32, 34) of the receptacle (26) or • the receptacle (26) has a round, preferably elliptical or circular, cross-sectional shape, wherein the holding fingers (30) extend in a direction radial to the longitudinal axis L into the receptacle (26); and wherein • the holding fingers (30) partially mesh with one another.

Description

Pneumatic tube for transporting sample tubes

The invention relates to a pneumatic tube carrier for transporting sample tubes. In medical practice, such sample tubes are used as sample containers for the removal, processing, transport and at least short-term storage of body fluids such as blood, cerebrospinal fluid, pleural fluid and the like. The sampling tubes are usually made of plastic and can be designed in particular as so-called sampling tubes with a mostly syringe-like structure. In practice, the sample tubes are often transported by means of a pneumatic tube system to a predetermined destination inside or outside the building, for example a diagnostic laboratory. So-called pneumatic tube carriers, which are also referred to as shipping cartridges, are used for this purpose. The pneumatic tube carriers have in the Rule on a tubular body, which is provided at both ends with an opening through which the pneumatic tube can be equipped with the sample tubes and emptied again. The openings can usually be closed with a swivel or hinged lid.

For example, DE 10 2018 205 639 A1 discloses a magazine insert for such a pneumatic tube carrier for receiving the sample tubes and a pneumatic tube carrier with this magazine insert.

From AT 12 017 Ul an insert for a tube with a frame for receiving test tubes is known. The frame has a support column with at least one base and several holders for holding the sample tubes.

The pneumatic tube carriers and the sample tubes arranged in them are often exposed to enormous forces of up to 10 times the acceleration due to gravity (10g) and sometimes violent vibrations during normal ferry operation of the pneumatic tube system. For example, when transporting blood samples, this can lead to hemolysis, i. H. a destruction of red blood cells, and consequently lead to a falsification of measurement results of diagnostic parameters to be determined in each case.

In practice, the pneumatic tube carriers for the transport of sampling tubes are therefore sometimes lined with a foam material in order to achieve a certain damping of the vibrations. However, this makes it difficult to empty the pneumatic tube carrier. This may also result in hygienic problems, especially since the foam material used is not or only slightly suitable for hygienic processing. Other pneumatic tube carriers have a magazine with slide-in channels for the sample tubes, into which the sample tubes have to be threaded, which is time-consuming. The insertion channels can have leaf spring elements, by means of which the sample tubes are held clamped in the respective insertion channel. It is therefore the object of the invention to provide a pneumatic tube for the transport of sample tubes, which on the one hand is easy to handle and in which uncontrolled movements of the sampling tubes within the pneumatic tube during shipping are avoided.

The task relating to the pneumatic tube carrier is achieved by a pneumatic tube carrier having the features specified in claim 1.

According to the invention, the pneumatic tube carrier has a tubular base body which has an opening at both ends that can be closed with a cover. A receptacle is arranged inside the base body, into which (via one of the openings) several sample tubes can be inserted next to and behind one another in the direction of the longitudinal axis of the base body. In other words, the pneumatic tube carrier includes a single common transport chamber for the sample tubes to be transported. The pneumatic tube carrier has a holding device with a large number of elastically deformable holding webs or holding fingers, which are each arranged at an angle to the longitudinal axis and which each protrude into the receptacle in such a way that each sample tube pushed into the receptacle is between several of the holding fingers (= holding webs ) is held clamped.

The pneumatic tube carrier can be loaded with sample tubes particularly easily and quickly. The recording with the holding fingers or holding webs allows a spatially highly variable positioning of the sample tubes in the pneumatic tube carrier, so that the often time-consuming threading of the sample tubes into defined tubular insertion channels is no longer necessary. Due to the fact that the sample tubes can only be contacted and held by elastically deformable holding fingers, a sufficiently cushioned storage of the sample tubes can be achieved. In particular, radial forces acting on the pneumatic tube carrier during transport in the pneumatic tube system can be effectively dampened. As a result, changes in the liquids contained in the sample tubes, in particular whole blood, caused by vibration can be counteracted. It should be noted that in the recording arranged sample tubes are contacted solely by the holding fingers or possibly by another sample tube. The holding device thus ensures (fully) floating storage of the sample tubes in the receptacle. In addition, a particularly simple removal of the sample tubes is made possible. For example, the sample tubes can be easily moved out of the pneumatic tube carrier by inserting a stamp, which may be automated.

In an alternative according to the invention, the receptacle has a polygonal, in particular rectangular, cross-sectional shape. In this case, the retaining fingers extend into the receptacle from at least two opposite sides or side walls of the receptacle.

According to another alternative according to the invention, the receptacle has a round, preferably elliptical or circular, cross-sectional shape, with the retaining fingers extending into the receptacle in a direction radial to the longitudinal axis. Here the interior volume of the pneumatic tube carrier can be used particularly efficiently. The assembly of the holding fingers can also be simplified.

According to the invention, the holding fingers partially mesh with one another. As a result, a particularly reliable mounting of even small sample tubes can be achieved. In addition, as a result fewer or thinner holding fingers can be used, which is advantageous for the production costs.

According to the invention, some of the holding fingers or all of the holding fingers preferably have a length which corresponds to at least three times, preferably at least five times, their respective diameter. As a result, a holding finger can contact a plurality of sample tubes and a sufficient density of the holding fingers per unit volume of the interior of the base body can be provided.

The holding fingers or also the entire holding device can consist in particular of an elastomer or of rubber. As a result, the Holding fingers elastically deformable. As a result, a particularly gentle storage of the sample tubes can be achieved.

Silicone has proven to be particularly suitable as an elastomer. Silicone is temperature stable, autoclavable and gas sterilizable. This is important for laboratory transport in clinical settings.

According to a particularly preferred development of the invention, the holding fingers are at least partially, preferably all, designed as hollow bodies. As a result, an even further improved damping behavior can be achieved, which is advantageous for the integrity of the liquids contained in the sample tubes.

According to a preferred development of the invention, the holding fingers are each arranged on a holding mat. As a result, the mounting of the holding device in the base body of the pneumatic tube carrier can be simplified.

In terms of manufacturing technology, each retaining mat and the retaining fingers arranged thereon are preferably each formed in one piece, in particular as an injection-molded part. This enables a particularly simple assembly and manufacture of the pneumatic tube carrier.

With a view to the unavoidable wear of the holding device during operational use and for the purpose of a particularly simple hygienic preparation of the pneumatic tube carrier, the holding device is preferably arranged to be exchangeable. The holding device can be designed as part of a cartridge insert of the base body.

In their unloaded neutral position, a large part or all of the holding fingers are preferably arranged orthogonally in a two-dimensional projection or at an angle .alpha.with 70.degree.<.alpha.<90.degree. relative to the longitudinal axis. The retaining fingers can preferably be deflected by a deflection angle β with β>50° from their neutral position relative to the longitudinal axis. As a result, the sample tubes can be particularly easy to accommodate the Pneumatic tube carrier introduced and removed from the pneumatic tube carrier together in a pneumatic tube station, for example by means of a stamp that can be inserted into the pneumatic tube carrier or a brush head. Such individual stamps/brushes have long been known and in use at pneumatic tube stations as (automated) removal aids.

The cover of the pneumatic tube carrier can basically be designed as a hinged, swiveling or sliding cover. In the case of the hinged lid, the axis of rotation of the lid is arranged to run transversely to the longitudinal axis of the base body, while in the case of the pivoting lid it is arranged to run parallel or essentially parallel to the longitudinal axis.

The base body and the holding device can be transparent, at least in sections, to light in the spectral range that is visible to humans. As a result, when handling the pneumatic tube carrier, the filling level of the pneumatic tube carrier, any liquids that may have leaked out of the sample tubes, and also sample tubes that were mistakenly left in the pneumatic tube carrier can be recognized early and conveniently by the user.

According to the invention, the pneumatic tube carrier can preferably be autoclaved and/or gas-sterilized several times.

Further advantages of the invention result from the description and the drawing. Likewise, the features mentioned above and those detailed below can be used according to the invention individually or collectively in any combination. The invention is explained in more detail below using two exemplary embodiments shown in the drawing. The embodiments shown and described are not to be understood as an exhaustive list, but rather have an exemplary character for the description of the invention.

Show in the drawing: 1 shows a pneumatic tube carrier with a tubular base body with openings that can be closed on both sides by means of a lid and an individual receptacle for a large number of sample tubes arranged in the base body, the receptacle having a rectangular cross-sectional shape and with a holding device with a large number of flexibly deformable holding fingers for the sample tubes is provided, in a first sectional view;

FIG. 2 shows the pneumatic tube carrier according to FIG. 1 in a further sectional view;

Fig. 3 is a detail of the holding device according to FIG

sectional view;

4 shows the pneumatic tube carrier according to FIG. 1 together with a

removal stamp of a pneumatic tube station; in a perspective view;

5 shows a further pneumatic tube carrier, which is characterized by a receptacle for the sample tubes with a circular cross-sectional shape, with the holding fingers of the holding device protruding inwards into the receptacle in a radial direction, in a sectional view; and

6 shows the pneumatic tube carrier according to FIG. 5 together with a removal stamp of a pneumatic tube station in a perspective detailed section.

Figs. 1 and 2 show a first embodiment of a pneumatic tube carrier 10 for transporting sample tubes 12, here so-called sampling tubes for body fluids such as blood, cerebrospinal fluid, urine, pleural fluid and the like, within a pipeline system of a pneumatic tube system known per se (not shown). The pneumatic tube carrier 10 has a sleeve-like or tubular body 14 which extends along the longitudinal axis L of the pneumatic tube carrier 10 . The base body 14 is provided with an opening 16 at both ends. The two openings 16 of the pneumatic tube carrier 10 can each be closed with a cover 18 and are used for loading and unloading the pneumatic tube carrier 10. Two treads 20 are arranged on the outside of the pneumatic tube carrier 10 in a manner known per se, which consist, for example, of a textile or a fleece band be able. If necessary, additional circumferential sealing rings 22 can be provided in order to enable improved sealing contact between the pneumatic tube carrier 10 and the wall of the pipeline system.

The cover 18 are pivoted here on the base body 14 of the pneumatic tube carrier 10 in each case pivoted about a pivot axis designated 24 . The pivot axis 24 is aligned parallel or substantially parallel to the longitudinal axis L of the base body 14 . The cover 18 can alternative embodiments also be designed as a hinged cover or as a so-called sliding cover. This is of secondary importance for the invention.

Inside the tubular base body 14 there is a receptacle for the sample tubes 12 which is denoted overall by 26 . The receptacle 26 has an overall rectangular cross-sectional shape with rectangular openings 16 designed accordingly. The openings 16 each have a cross-sectional area Ai which corresponds to a multiple of the cross-sectional area A ₂ of each of the sample tubes 12 to be transported.

In the common receptacle 26 , for example, several sample tubes 12 are arranged one behind the other in the direction of the longitudinal axis L of the base body 14 and also next to one another. Because of the openings 16, which are large in comparison to the sample tubes 12, the sample tubes 12 can be introduced into the pneumatic tube carrier 10 in a simple and convenient manner. Time-consuming threading of the sample tubes 12 into the receptacle 26 is no longer necessary. A holding device 28 is used to hold the sample tube 12 within the receptacle 26. The holding device 28 has a multiplicity of elastic, preferably rubber-elastic, deformable holding webs or holding fingers 30. The holding fingers 30 are each arranged at an angle to the longitudinal axis L and protrude from two opposite side walls or sides 32, 34 of the receptacle 26 into the receptacle, so that each sample tube 12 inserted into the receptacle 26 is held clamped between several of the retaining fingers 30 is. The density of the holding fingers 30 per unit volume of the receptacle 26 is preferably chosen such that each sample tube 12 is held between at least 8 or more holding fingers 30 . It should be noted that in this design the sample tubes 12 arranged in the receptacle are only contacted by the holding fingers or possibly by another sample tube 12 . Fully floating storage of the sample tubes in the receptacle 26. Depending on how the receptacle 26 is equipped, the holding fingers 30 can also contact several sample tubes 12 at the same time.

The holding fingers 30 on one side 32, 34 and the holding fingers 30 on the respective other side 32, 34 mesh at least partially with one another. In the exemplary embodiment shown here, however, according to Figure 3, the holding fingers 30 each have such a length 36 that the holding fingers 30 on the two sides 32, 34 (= side walls) of the receptacle 26 are spaced apart from one another and between them there is an insertion channel 38 for the sample tubes 12 define. The length of the holding fingers can, for example.

The holding fingers 30 can have a uniform maximum thickness or a uniform diameter 44 or differ from one another in their respective diameter 44 . According to FIG. 3, the retaining fingers can taper conically and, for example, have a diameter of 3 millimeters at the base and 1.5 millimeters at the tip. The length 36 of Retaining finger 30 is at least three times, preferably at least five times, their respective diameter 44. Here, the length 36 can be 15 millimeters, for example. It should be noted that the holding fingers 30 according to FIG. 3 can be designed at least partially as hollow bodies in order to achieve an even further improved damping capacity of the holding fingers 30 . As a result, the sample tubes 112 can be better protected against impacts and vibrations during their transport in the pneumatic tube carrier 10 .

The holding fingers 30 can each be arranged on a support element in the form of a support mat 48 on the foot side. The respective carrier mat 48 and its holding fingers 30 or the entire holding device can be designed in one piece, in particular as an injection molded part. To this extent, the carrier mat 48 can be flexibly deformable in order to enable simple assembly of the holding device 28 . The holding device 28 can in particular consist of an elastomer or rubber. The elastomer is preferably silicone to enable simple hygienic processing with a long service life. The carrier mat can be glued to the base body or attached to the base body in some other way.

Most or all of the retaining fingers 30 are in their unloaded neutral position—in a two-dimensional projection—preferably orthogonal or essentially orthogonal or at an angle o with 70°<o<90° relative to the longitudinal axis L of the base body 14 . The holding fingers 30 can preferably be deflected polyaxially by a deflection angle β with β>20°, in particular β>50°, from their neutral position shown in FIG. As a result, the sample tubes 12 can be clamped particularly securely between the holding fingers 30 . In addition, the sample tubes 12 can be inserted into the receptacle 26 and removed from it again in a simplified manner.

The entire holding device 28 can be exchanged, in particular also as part of a cartridge (not shown in the drawing), arranged in the base body 14 be. This simplifies an exchange of the holding device 28, for example due to wear, as well as an intermittent hygienic preparation (in particular disinfection or sterilization) of the pneumatic tube carrier 10.

The base body 14 and the holding device 28 can be permeable at least in sections for light in the spectral range visible to humans in order to facilitate a visual inspection by a user. The pneumatic tube carrier 10 can preferably be autoclaved or gas sterilized several times overall.

Fig. 4 shows the pneumatic tube carrier 10 during the removal process within a pneumatic tube station 100. The two covers 18 of the pneumatic tube carrier 10 are open. A removal plunger 102 of pneumatic tube station 100 arranged to be movable in the direction of the arrow is arranged coaxially to the longitudinal axis L of the base body 14 and aligned with its T-shaped free end 104 to the opening of the receptacle 26 of the base body 14 in the axial direction. By inserting the removal plunger 102 into the receptacle and, if necessary, passing the removal plunger 102 through the receptacle 26, the sample tubes 12 held within the receptacle 26 can be easily moved out of the pneumatic tube carrier 10 in the axial direction via the downward-pointing opening 16.

5 shows a further embodiment of a pneumatic tube carrier 10, which differs from the embodiment explained above in connection with FIGS. 1 to 4 essentially in that the receptacle 26 has a circular cross-sectional shape and the retaining fingers 30 all extend in a radial direction toward the longitudinal axis L of the base body 12 and into the receptacle 26 . The holding fingers 30 are also arranged here on a carrier mat 48 and are formed in one piece with it. Here, too, the carrier mat 48 is designed in one piece together with the holding fingers 30 . This embodiment allows an even further improved utilization of the interior volume of the base body 14 of the pneumatic tube carrier 10. Fig. 6 shows a sectional perspective view of the pneumatic tube carrier 10 shown in Fig. 5 during the removal of the sample tubes 12 arranged therein within a pneumatic tube station 100 Cross-sectional area of the recording 26 coordinated circular free end 104 has.

It goes without saying that the receptacle of the pneumatic tube carrier 10 can also have a different geometric cross-sectional shape, for example a triangular or an oval or elliptical cross-sectional shape.

Claims

Patent claims Pneumatic tube carrier (10) for the transport of sample tubes (12) for body fluids along a pneumatic tube system, comprising

• a tubular base body (14) which has an opening (16) at both ends which can be closed by a cover (18),

• a receptacle (26) which is arranged within the base body (14) and into which a plurality of sample tubes (12) can be inserted next to one another and one behind the other in the direction of the longitudinal axis of the base body (14);

• a holding device (28) with a large number of elastically deformable holding fingers (30) which are each arranged running obliquely to the longitudinal axis L and which each protrude into the receptacle (26) in such a way that each sample tube ( 12) held clamped between a plurality of the holding fingers (30); whereby

• the holding fingers (30) or the holding device (28) consist of an elastomer or rubber; whereby

• the receptacle (26) has a polygonal, in particular rectangular, cross-sectional shape and the retaining fingers (30) of two opposing side walls (32, 34) of the receptacle (26) protrude into the receptacle (26) or

• the receptacle (26) has a round, preferably elliptical or circular, cross-sectional shape, with the retaining fingers (30) extending into the receptacle (26) in a direction radial to the longitudinal axis L; and wherein the retaining fingers (30) partially intermesh. Pneumatic tube carrier (10) according to Claim 1, characterized in that at least some of the holding fingers (30) or all of the holding fingers (30) have a length (36) which corresponds to at least three times, preferably at least five times, their diameter (44). Pneumatic tube carrier (10) according to Claim 1 or 2, characterized in that the elastomer is silicone. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that the retaining fingers are at least partially designed as hollow bodies. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that the holding fingers (30) are each arranged on a carrier mat (48). Pneumatic tube carrier (10) according to Claim 5, characterized in that each carrier mat (48) and the retaining fingers (30) arranged thereon are constructed in one piece, in particular as an injection molded part. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that the holding device (28) is arranged in the base body (14) in an exchangeable manner, in particular in the form of a cartridge. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that a large part or all of the retaining fingers (30) in their unloaded neutral position are arranged at an angle o with o between 70° and 90° relative to the longitudinal axis L and preferably at an angle Angle ß with ß> 50 ° relative to the longitudinal axis L can be deflected from its neutral position. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that the covers (18) are constructed as hinged or pivoting covers. - 15 - pneumatic tube carrier (10) according to any one of the preceding claims, characterized in that the base body (14) and the holding device (28) are transparent at least in sections for light in the spectral range visible to humans. Pneumatic tube carrier (10) according to one of the preceding claims, characterized in that the pneumatic tube carrier (10) can be autoclaved or gas sterilized.