EP1998181B1 - Liquid container with variable flue - Google Patents

Description

The invention relates to a liquid container having an upper opening and extending into alignment with the upper opening into the container, tubular removal chute for liquid removal by means of a to be introduced from above into the extraction chimney extraction element, in particular a pipette, wherein the removal chimney in its lower, the container bottom adjacent end region has a liquid-permeable zone.

More particularly, the invention relates to liquid containers used as reagent liquid containers in automatic analyzers. When used in such an automatic analyzer, reagent liquid is taken from the liquid containers by automatic pipetting. This is done in a faster cycle in more modern systems to allow high throughput of relevant analysis operations. The liquid container by means of a transport device, for example in the form of a rotor quickly supplied to the pipetting and braked there, whereupon the automatic pipette or suction needle through the upper opening of the liquid container passes into the extraction chimney to suck liquid. With high throughput automated analyzers, each individual pipetting operation, including the positioning of the liquid container in the pipetting zone, has extremely short single-second cycle times. The problem arises that during the abrupt stopping of the liquid container in the pipetting zone, the liquid in the container sloshes and possibly splashes, so that a fairly balanced liquid level often sets only after a respective waiting time that lasts longer than the required short pipetting cycle time for the high-throughput operation. The pipetting with still strongly fluctuating liquid level in The extraction chimney should usually be avoided, since in this case the pipette tip is undesirably wetted with the liquid over a relatively large area and thus a comparatively large entrainment volume of liquid adheres to the pipette tip when the pipette is withdrawn from the liquid container and then at further Pipetting causes contamination. In order to avoid this, the pipette tip during pipetting should also dip only slightly into the liquid to be pipetted and the level in the liquid container should be as calm as possible. It should also be avoided that the pipette draws air due to a fluctuating liquid level. Furthermore, foaming in the extraction chimney should be suppressed.

The state of the art of reaction liquid containers with removal chimney can, for example, on the WO 97/12677 A1 , on the US 5,102,631 or on the DE 38 38 278 C1 to get expelled. When the liquid container from the WO 97/12677 A1 the tubular discharge chimney is provided at its upper end with a radially outwardly projecting flange, with which it is suspended from a spout of the container opening. In this case, the completely open lower end of the removal chimney extends into the vicinity of the bottom of the liquid container, so that liquid communication between the removal chimney and the surrounding interior region of the liquid container can only take place via a narrow bottom gap through the lower opening of the removal chimney. So that pressure equalization between the interior of the container and the environment can take place during pipetting, slit-like wall thickness reductions are provided in the upper region of the extraction chimney, which are intended to allow an influx of air between the mouth of the liquid container and the mantle of the extraction chimney.

From the DE 38 38 278 C1 a liquid container with removal chimney is known in which the cross section of the removal chimney is substantially smaller than the cross section of the upper container opening, said removal chimney interspersing a screwed with the mouth grommet screw cap and is fixed on this. A through hole in the screw cap allows pressure equalization between the container interior and the external environment. The removal chimney extends into the vicinity of the container bottom, so that liquid exchange between the discharge chimney and the surrounding interior of the container can take place through the open underside of the removal chimney. In a further embodiment of the DE 38 38 278 C1 the outer circumference of the removal chimney at its upper end and the inner circumference of the discharge chimney surrounding at its upper end spout are only slightly different, so that between the outside of the extraction chimney and the inner surface of the spout not sufficiently large ventilation path for pressure equalization between the container interior and the environment remains. For pressure equalization, a through hole in the jacket of the extraction chimney is provided at its upper end. The removal chimney is substantially completely open at its lower end, with spacer webs being provided at the lower end of the withdrawal chimney.

The from the US 5,102,631 known liquid container is similar to the last-mentioned embodiment of the DE 38 38 278 C1 constructed and thus also has a through hole in the jacket of the discharge chimney at the upper end. The extraction chimney extends to the bottom of the liquid container, but large lateral openings are provided in the jacket of the extraction chimney at the lower end.

According to the operating principle of the removal chimney, it is provided in the known examples that between the lower end of the removal chimney and the opposite container bottom only a small distance and thus only a narrow flow gap to form a large flow resistance is given, so that fluctuations in the container volume outside As far as possible, the discharge chimney can only have a damped effect in the withdrawal chimney. The known extraction chimneys thus have at their end adjacent the container bottom end a liquid-permeable zone with a low fluid permeability on.

However, this necessary for the desired function of the withdrawal chimney per se limitation of the liquid transmittance also brings disadvantages, namely in such liquid containers of the type considered here, which are to be filled by the discharge chimney from the upper opening forth first with liquid. The filling must be very slow, since the level in the discharge chimney, due to the low fluid permeability of the liquid-permeable zone increases much faster than the level in the container area outside the discharge chimney. Overfilling may cause overflow of liquid at the top of the container.

Even with conventional liquid containers in which the removal chimney is to be used only after filling, there was the problem that overflow of liquid through the upper container opening can only be avoided if the discharge chimney is introduced comparatively slowly into the container, since due to the low Liquid permeability of the liquid-permeable zone at the bottom of the chimney end, the liquid can not rise quickly enough in the chimney.

From the BE 533 852 A An article according to the preambles of claims 1 and 2 is known.

The invention has for its object to provide a liquid container of the type mentioned, which can be filled quickly through the upper opening and through the removal chimney and yet in the liquid removal operation, the desired properties of calming the liquid level within the extraction chimney against the fluctuations in the container area outside of the Removal chimney has.

To solve this problem is in one aspect, starting from a Liquid container of the type mentioned according to the invention proposed further form the liquid container according to the features of the characterizing part of claim 1. To solve this problem is proposed according to the invention in a further aspect, starting from a liquid container of the type mentioned, further form the liquid container according to the features of the characterizing part of claim 2.

For a filling operation of the liquid container, the removal chimney and thus the liquid-permeable zone can be used e.g. be set so that their fluid permeability is relatively large. After the filling process, the liquid-permeable zone can then be set back into a state with low liquid permeability, so that the extraction chimney can fulfill its desired function in liquid removal operation of the liquid container. In particular, the liquid transmission capacity of the liquid-permeable zone is not completely suppressed in any of the settings of the extraction chimney. In the position of minimum liquid permeability, liquid exchange can thus take place between the removal chimney and the surrounding container body.

Preferably, the liquid-permeable zone comprises at least one opening in the lower end region of the extraction chimney whose effective opening cross-section is adjustable, this being done by the rotational movement or the lifting movement of the extraction chimney or a part thereof relative to the liquid container bottom.

According to the first aspect of the invention the Ent-nah-mekamin has a pipe section which extends downwardly from the upper container opening and a pipe receptacle provided on the container bottom for the pipe section, whereby the pipe section and the pipe receptacle are inserted into one another. and are adjustable relative to each other to the effective Opening cross-section of the liquid-permeable zone to change. In such an embodiment of the invention include the liquid-permeable zone lateral openings in the pipe section and lateral openings in the pipe receiving in the lower end of the extraction chimney, wherein lateral openings of the pipe section and lateral openings of the pipe receiving relative to each other in common alignment are aligned to the effective opening cross-section of the liquid-permeable zone.

Alternatively, according to the second aspect of the invention, the change in the transmittance of the liquid-permeable zone simply by the fact that a pipe section of the discharge chimney extending from the upper container opening closer to the container bottom is brought closer to the container bottom, so that only a small flow gap between the container bottom and bottom End of the pipe section remains. This is then the condition of the lower fluid permeability of the liquid-permeable zone. By raising the pipe section and thus increasing the distance between the lower end of the pipe section and the container bottom, the liquid permeability of the liquid-permeable zone is then increased.

Preferably, the removal chimney is securely received in the liquid container, so that it is not removable from the latter under normal handling conditions even when the liquid container is open.

• Bereitstellen des Flüssigkeitsbehälters in einer automatischen Füllstation,
• Sicherstellen, dass für einen folgenden Einfüllschritt der Entnahmekamin in dem Flüssigkeitsbehälter in der Stellung größeren Flüssigkeitsdurchlassvermögens der flüssigkeitsdurchlässigen Zone eingestellt ist,
• Einfüllen der Flüssigkeit durch den Entnahmekamin hindurch in den Flüssigkeitsbehälter, während der Entnahmekamin in der Stellung größeren Flüssigkeitsdurchlassvermögens der flüssigkeitsdurchlässigen Zone eingestellt ist,
• Verschließen des Flüssigkeitsbehälters,
• Einstellen des Entnahmekamins in die Stellung minimalen Flüssigkeitsdurchlassvermögens der flüssigkeitsdurchlässigen Zone als Vorbereitungsschritt für die Entnahme von Flüssigkeit aus dem Behälter.

The invention further provides a method for preparing a liquid container according to one of the preceding claims for the provision of a liquid in an automatic analyzer, comprising the steps:

• Providing the liquid container in an automatic filling station,
• Make sure that for a subsequent filling step the extraction chimney in the liquid container is set in the position of larger liquid permeability of the liquid-permeable zone,
• Filling the liquid through the extraction chimney into the liquid container while the extraction chimney is set in the position of larger liquid permeability of the liquid-permeable zone,
• Closing the liquid container,
• Adjusting the discharge chimney in the position of minimum liquid permeability of the liquid-permeable zone as a preparation step for the removal of liquid from the container.

The setting of the removal chimney in the position of greater fluid permeability can be done before the introduction of the liquid container in the automatic filling station or after. What is essential is that the normally automatic and fast filling step occurs while the discharge chimney is set in the position of greater liquid permeability of the liquid-permeable zone.

The setting of the removal chimney in the position of minimum liquid permeability occurs after filling, this preparation step for the removal of liquid from the container prior to closing the liquid container or thereafter and possibly only in another place, such as in an automatic analyzer, can take place.

It is thus proposed a particularly advantageous use of the liquid container according to the invention, in which the liquid can be filled in a fast-cycling automatic filling station in high-throughput operation to prepare the liquid container for the subsequent provision of the liquid in a high-speed automatic analyzer, wherein the Fluid removal in the automatic analyzer by aspirating fluid from the fluid reservoir by means of a pipette or the like, while the extraction chimney is set in the position of minimum liquid permeability of the liquid-permeable zone. It is thus high-throughput operation in the automatic filling station and high-throughput operation in the automatic analyzer with the liquid container according to the invention possible, without having to accept disadvantages compared to the prior art of the generic liquid container in purchasing.

Fig. 1a und Fig. 1b

zeigen in einer Schnittdarstellung ein erstes Ausführungsbeispiel eines erfindungsgemäßen Flüssigkeitsbehälters mit Entnahmekamin mit zwei verschiedenen Grenzeinstellungen des Öffnungsquerschnittes der flüssigkeitsduchlässigen Zone des Entnahmekamins.

Fig. 2a und Fig. 2b

zeigen ein zweites Ausführungsbeispiel eines erfindungsgemäßen Flüssigkeitsbehälters mit Entnahmekamin mit zwei verschiedenen Grenzeinstellungen des Flüssigkeitsdurchlassvermögens der flüssigkeitsdurchlässigen Zone des Entnahmekamins.

Fig. 3a und 3b

zeigen eine Variante des zweiten Ausführungsbeibeispiels.

Embodiments of the invention are explained in more detail below with reference to the figures.

Fig. 1a and Fig. 1b

show in a sectional view a first embodiment of a liquid container according to the invention with removal chimney with two different limit settings of the opening cross-section of the flüssigkeitsduchlässigen zone of the removal chimney.

Fig. 2a and Fig. 2b

show a second embodiment of a liquid container according to the invention with removal chimney with two different limit settings of the liquid permeability of the liquid-permeable zone of the extraction chimney.

Fig. 3a and 3b

show a variant of the second exemplary embodiment.

In the figures, the vertical longitudinal section runs centrally through the discharge chimney 3 or 3a.

The liquid container 1 is a reagent liquid container which is used in the manner described in the beginning in automatic analyzers.

The liquid container 1 has at its upper end a screw cap opening 5, starting from which a pipe section 7 of the discharge chute 3 extends vertically into the container interior. The container bottom 9 has a tube receptacle 11, which has a pot-like shape with two, for example, rectangular, open at the top incisions 13. The incisions 13 are in the direction of the Fig. 1a and 1b in flight one behind the other on diametrically opposite sides of the tube receptacles eleventh

The pipe section 7 is received with its lower end in the pipe receptacle 11, in such a way that it lies with its outer circumference the inner periphery of the pipe receptacle 11 closely adjacent and preferably touching. The tube holder 11 thus forms a pivot bearing for the pipe section 7 of the discharge chimney 3, so that the pipe section 7 is rotatable about the vertical axis of rotation 15 between two defined Drehanschlagstellungen. In this case, lateral cuts 17, which are provided at diametrically opposite regions of the pipe section 7 and do not extend beyond the uppermost edge of the pipe receptacle 11 also upward, are rotated relative to the notches 13 of the pipe receiving. The cuts 17 and 13 represent lateral openings in the pipe section 7 and in the pipe receptacle 11 and together form a liquid-permeable zone 18 of the discharge chimney 3, whose effective opening cross-section depends on the extent to which the lateral openings 17 of the pipe section 7 in common alignment with the lateral openings 13 of the pipe receiving 11 are. In Fig. 1a the lateral openings 17 of the pipe section 7 are completely aligned in alignment with the lateral openings 13, so that the openings 13, 17 show a maximum overlap. This is the limit position of the maximum effective opening cross-section of the liquid-permeable zone 18 of the discharge chimney 3, ie the defined setting of the larger liquid permeability of the liquid-permeable zone. It can take place in this situation, relatively good fluid exchange between the interior of the discharge chimney 3 and the container volume outside of the discharge chimney 3, which is responsible for filling the Liquid container 1 through the opening 5 and the discharge chimney 3 is important.

For a later liquid withdrawal operation, in which liquid is to be sucked from the top of the discharge chimney 3 by means of a pipette or suction needle, good liquid communication between the interior of the withdrawal chimney and the container volume outside the withdrawal chimney is very unfavorable, since fluctuations of the liquid in the container volume outside the Removal chimney 3 quickly and only slightly attenuated transferred to the interior of the withdrawal chimney 3. This problem is with the liquid container according to Fig. 1 a and Fig. 1b achieved by turning the pipe section 7 relative to the pipe receptacle 11 of the discharge chimney 3, the common effective opening cross section of the side openings 13 and 17 of the pipe section 7 and the pipe receptacle 11 can be set to a smaller value, as in Fig. 1b is illustrated. Fig. 1b shows the discharge chimney 3 in the limit of minimum liquid transmittance of the zone 18 with a small effective opening cross-section of the liquid-permeable zone 18, as it is to be selected for the liquid extraction operation. Rotary stops, which prevent the tube section 7 from being turned beyond the limits shown, are in Fig. 1a and Fig. 1b Not shown.

It should be noted that in the figures ventilation ducts or distance bays between the inner surface 6 of the screw plug and the outer circumference of the pipe section 7 or ventilation openings in the upper region of the pipe section 7, which provide a pressure equalization between the outside environment and the container interior, are not shown. However, such upper ventilation measures are provided according to the invention in the practice. For this purpose, various proposals from the prior art can be used. This also applies to the second embodiment according to the FIGS. 2a and 2b ,

In the illustration of the second embodiment in the Fig. 2a and 2b are for elements that are elements in the Fig. 1a and 1b have corresponded functionally according to their corresponding, corresponding reference numerals have been used for identification. It can thus for the understanding of the second embodiment in this respect to the explanations to the first embodiment according to Fig. 1a and 1b to get expelled. The following explanations may therefore be limited to the differences of the second embodiment to the first embodiment.

In the second embodiment, the liquid passage capacity of the liquid-permeable zone 18 is varied by a lifting movement of the pipe section 7a relative to the vessel bottom 9. The liquid-permeable zone is defined by the annular gap 19, while the discharge chimney pipe section 7a is raised Fig. 2a larger than when lowered extraction chimney pipe section 7a according to Fig. 2b and defined by the crenelated spaces 21. Slings 20 and 22 ensure that defined end positions for the stroke adjustment of the pipe section 7a are possible, as this in the Fig. 2a and 2b can be seen. Fig. 2a shows a provided for filling the container 1 limit setting of the removal chimney 3a. Fig. 2b shows the favorable for the liquid extraction operation limit position of the discharge chimney 3a. Also in the setting of minimum liquid permeability of the liquid-permeable zone according to Fig. 2b For example, fluid exchange through zone 18 may occur.

A variant of the second embodiment with a modification of the lower end of the pipe section 7a is in the Fig. 3a and 3b shown.

In the embodiment of the Fig. 3a and 3b has the pipe section 7a at its lower end four spacer webs 22, which ensure that in the lowered state of the pipe section 7a according to Fig. 3b this is not occlusive with its lower edge on the bottom 9 and also on the circumference of the circumference circumferential collar 24th maintains a distance to the vessel bottom 9, so that the liquid-permeable zone 18 in Fig. 3b With reduced fluid permeability, fluid communication between the interior of the withdrawal chimney 3a and the container volume outside the withdrawal chimney can take place. Fig. 3a shows a provided for filling the container 1 setting the removal chimney 3a. Fig. 3b shows the favorable for the liquid removal operation position of the removal chimney 3a.

Numerous modifications of the described embodiments are conceivable. Thus, the extraction chimney can e.g. be adjustable by a combined lifting and turning movement. This may in particular be a screwing movement of the removal chimney.

The extraction chimney can in particular already be mounted therein before the filling of the liquid container.

Claims (6)

1. Liquid container with an upper opening (5) and with a tube-type withdrawal chimney (3) flush with the opening (5) reaching into the container (1) for removing liquid by means of a liquid removal element to be introduced into the withrawal chimney (3), in which the withdrawal chimney (3) has a liquid permeable zone (18) in its lower end area near the bottom of the container (9), in which the withdrawal chimney (3) may be adjusted with regard to the liquid permeability capacity of the liquid permeable zone (18) between a defined limit setting of minimal liquid permeability capacity and a defined setting of greater liquid permeability capacity whilst remaining in the container, in which means of stopping (20, 22) and/or means of latching are provided on the withdrawal chimney (3) and/or on the container (1), in order to define the limit settings of minimal liquid permeability capacity and greater liquid permeability capacity of the liquid permeable zone (18), characterised in that the withdrawal chimney (3) has a tube section (7) extending downwards from the upper container opening (5) and a tube seat (11) for the tube section (7) provided on the bottom of the container, in which the tube section (7) and the tube seat (11) may be inserted into each other and adjusted in relation to each other, in order to change the effective opening cross-section of the liquid permeable zone (18), in which side openings (17) in the tube section (7) and side openings (13) in the tube seat (11) in the lower end area of the withdrawal chimney (3) belong to the liquid permeable zone and in which side openings (17) of the tube section (7) and side openings (13) of the tube seat (11) may be aligned jointly flush in relation to each other through a turning movement of the withdrawal chimney (3) or a part of it in relation to the bottom of the liquid container (9), in order to increase the effective opening cross-section of the liquid permeable zone (18), in which a liquid exchange may also take place through the liquid permeable zone (18) in the limit settings of minimal liquid permeability capacity, in which ventilation channels or distance bays are provided between an inner surface (6) of the upper opening (5) and an outer circumference of the withdrawal chimney (3) or ventilation openings are provided in the upper area of the withdrawal chimney (3) for equalising the pressure between the outside environment and the inside of the container in both end positions.
2. Liquid container with an upper opening (5) and with a tube-type withdrawal chimney (3) flush with the opening (5) reaching into the container (1) for removing liquid by means of a liquid removal element to be introduced into the withrawal chimney (3), in which the withdrawal chimney (3) has a liquid permeable zone (18) in its lower end area near the bottom of the container (9), in which the withdrawal chimney (3) may be adjusted with regard to the liquid permeability capacity of the liquid permeable zone (18) by means of a lifting movement between a defined limit setting of minimal liquid permeability capacity, with a lifting movement towards the bottom of the container, and a defined setting of greater liquid permeability capacity, with a lifting movement away from the bottom of the container, whilst remaining in the container, in which means of stopping (20, 22) and/or means of latching are provided on the withdrawal chimney (3) and/or on the container (1), in order to define the limit settings of minimal liquid permeability capacity and greater liquid permeability capacity of the liquid permeable zone (18), characterised in that a means of stopping (22) is provided for defining an end position of the lifting movement towards the bottom of the container (9) and a further means of stopping (20) is provided for defining an end position of the lifting movement away from the bottom of the container (9), in which a liquid exchange may also take place through the liquid permeable zone (18) in the end position for the lifting movement towards the bottom of the container (9), in which ventilation channels or distance bays are provided between an inner surface (6) of the upper opening (5) and an outer circumference of the withdrawal chimney (3) or ventilation openings are provided in the upper area of the withdrawal chimney (3) for equalising the pressure between the outside environment and the inside of the container in both end positions.
3. Liquid container according to claim 1 or 2, characterised in that the liquid permeable zone (18) comprises at least one opening in the lower end area of the withdrawal chimney (3), the effective opening cross-section of which may be changed, in order to adjust the liquid permeability capacity of the liquid permeable zone (18) as required.
4. Liquid container according to claim 3, characterised in that the effective opening cross-section of the liquid permeable zone (18) may be adjusted through the turning movement or the lifting movement of the withdrawal chimney (3) or a part of it in relation to the bottom of the liquid container (9), in which the limit setting of minimal liquid permeability capacity is a defined latching position and/or defined stopping position.
5. Liquid container according to claim 4, characterised in that the turning or lifting adjusting movement of the withdrawal chimney (3, 3a) is possible between at least two defined stopping positions and/or latching positions, which are associated with different opening cross-sections of the liquid permeable zone (18).
6. Method for preparing a liquid container according to one of the previous claims for supplying a liquid in an automatic analysis device, comprising the steps:

   - Supplying the liquid container in an automatic filling station,

   - Ensuring that the withdrawal chimney in the liquid container is set in the position of greater liquid permeability capacity of the liquid permeable zone for a following filling step,

   - Filling the liquid into the liquid container through the withdrawal chimney, whilst the withdrawal chimney is set in the position of greater liquid permeability capacity of the liquid permeable zone,

   - Closing the liquid container,

   - Setting the withdrawal chimney in the position of minimal liquid permeability capacity of the liquid permeable zone as a preparatory step for withdrawing liquid from the container.

Images