EP0187167A1 - Liquid dispenser - Google Patents

Abstract

1. Means for the dosing of liquids, consisting of a measuring device (1) and a replaceable dosing vessel (3a-3m) which can be connected to the outlet (2) of the measuring device, and with which at least two ends are provided on the dosing vessel, of which ends, one (4) can be connected to the measuring device, in order directly or indirectly to connect the measuring space of the measuring device to the interior of the dosing vessel, at least temporarily, and at least one other end (5) is open (3a-3i) or is to be opened (3k), this opening being so constricted that the filled dosing vessel is unable to be uncontrollably emptied, when it is separated from the measuring device, characterised in that a resilient member (6a) consisting of a rubber-like material is disposed on that end (4) of the dosing vessel (3a-3m) which can be connected to the measuring device (1), which member seals the dosing vessel at this end, as long as it is not connected to the measuring device, and that the measuring device has disposed thereon a hollow needle (2), which penetrates the rubber-like material wit the connection of the dosing vessel to the measuring means, an open connection being provided between the measuring space of the measuring device and the internal volume of the dosing vessel, while the rubber-like material automatically re-seals the dosing vessel at the end (4), when the dosing vessel is separated from the measuring device.

Description

DISPENSER FOR LIQUIDS

The present invention relates to a device for receiving and storing or dispensing liquids one or more times, which consists of a measuring device (pipette) which does not come into contact with these liquids and an exchangeable metering vessel, the filled metering vessel being able to be separated from the metering device. without it emptying itself in an uncontrolled manner.

STATE OF THE ART

• a) Luft strömt schneller als Flüssigkeiten durch kleine Lecks im Meßwerk der Pipette oder zwischen ihrem Schaft und einem schlecht sitzenden Dosiergefäß. Im Vergleich zu Pipetten, mit deren Meßwerk die Flüssigkeit direkt dosiert wird, sind Pipetten mit einem Luftpolster daher störanfälliger, und die durch Lecks bedingten Fehler sind darüberhinaus auch schlechter zu erkennen. Die Hersteller dieser Geräte bemühen sich daher um eine hohe Formgenauigkeit nicht nur des Meßwerkes, sondern auch des Pipettenschaftes und der Dosiergefäße. Und die Anwender müssen beim Dosieren den Füllstand der Dosiergefäße genau kontrollieren und darauf achten, daß die aufgenommene Flüssigkeit nicht von allein aus den Dosiergefäßen tropft. Der Umgang mit diesen Pipetten verlangt daher von den Anwendern besonders viel Sorgfalt und Erfahrung, außerdem muß beim Aufstecken und Entfernen der Dosiergefäße sehr viel Kraft aufgewendet werden, um einen möglichst dichten Schluß zu erreichen.
• b) Das Volumen eines Gases ändert sich mit der Temperatur viel stärker als das einer Flüssigkeit, wobei sich ein Gas außerdem schneller als eine Flüssigkeit erwärmt: Dadurch Ist dieses Gerät anfällig gegen Schwankungen der Temperatur während des Pipettierens.
• c) Bedingt durch Oberflächenspannung neigen Flüssigkeiten dazu, ruckartig aus dem Dosiergefäß zu fließen. Diese Tendenz wird durch die Kompressibilität des Luftpolsters verstärkt, und die vom Meßwerk der Pipette vorgegebene Volumenänderung wird bei einem großen Luftpolster nur ungenau in eine Volumenänderung der zu dosierenden Flüssigkeit umgesetzt.
• d) Hält man die Pipette beim Aufnehmen der Flüssigkeit senkrecht, dann füllt sich das Dosiergefäß mit einem kleineren Volumen als bei schräg gehaltener Pipette. Diese Fehlerquelle ist durch die große Dehnungsfähigkeit der Luft und durch den von der Flüssigkeit erzeugten statischen Unterdruck bedingt.

In DT-PS 12 91 142 a dosing device for liquids is described, in which air is taken up or released by a pipette, whereby a liquid to be dosed, following the negative or positive pressure, into an interchangeable dosing vessel with the pipette in an air-tight connection filled or emptied from it. The volume taken up is dimensioned such that only the dosing vessel but not the pipette comes into contact with the liquid. By changing the dosing container, residues of previously dosed liquids can be removed, and a new liquid will not be contaminated if you continue dosing with the same pipette. The air cushion between the measuring device of the pipette and the liquid causes a number of error possibilities:

• a) Air flows faster than liquids through small leaks in the measuring device of the pipette or between its shaft and a poorly fitting dosing vessel. Compared to pipettes with whose measuring device the liquid is dosed directly, pipettes with an air cushion are therefore more susceptible to faults, and the errors caused by leaks are also more difficult to detect. The manufacturers of these devices therefore strive for high dimensional accuracy not only of the measuring mechanism, but also of the pipette shaft and the dosing vessels. And when dosing, the users must check the fill level of the dosing vessels precisely and ensure that the liquid absorbed does not drip out of the dosing vessels on their own. The handling of these pipettes therefore requires a great deal of care and experience from the users. In addition, a great deal of force must be applied when attaching and removing the dosing vessels in order to achieve the tightest possible seal.
• b) The volume of a gas changes with the temperature much more than that of a liquid, whereby a gas also heats up faster than a liquid: This makes this device susceptible to fluctuation temperature during pipetting.
• c) Due to surface tension, liquids tend to jerkily flow out of the dosing vessel. This tendency is reinforced by the compressibility of the air cushion, and the volume change specified by the pipette measuring mechanism is only imprecisely converted into a volume change of the liquid to be metered in the case of a large air cushion.
• d) If the pipette is held vertically when taking up the liquid, the dosing vessel fills with a smaller volume than when the pipette is held at an angle. This source of error is due to the large expansion capacity of the air and the static vacuum generated by the liquid.

The so-called capillary piston pipettes work without air cushions. The liquid is sucked into a capillary by a piston, both are wetted by the liquid. These devices dispense more precisely than the pipettes with air cushions, but they have the disadvantage that the wetted parts are usually not replaced after each sample because of the expenditure of time and the material costs. It is accepted that liquid will be carried over from one sample to the next.

With the devices mentioned so far, the absorption and dispensing of the liquids must follow one another in time. You cannot fill different dosing vessels with the same pipette, detach them from the measuring device, put them back on at any time and empty their contents. This is possible with disposable syringes, the piston rod of which can be clamped in the holder of a dosing device in any position (Stöcker, W., Acta histochem. (Jena), Suppl., In press). These syringes can be easily replaced and therefore dispensed without carryover. In the case of a syringe, however, the shapes of the plunger and the housing must match each other exactly and it also consists of at least two parts. Accordingly, their manufacture is considerably more complex than, for example, that of a metering vessel for a piston-stroke pipette. In addition, inserting the syringe into the measuring device is more cumbersome than attaching a metering vessel.

DT-OS 26 11 060 describes a dosing "element" which, after filling, could be separated from the pipette without becoming detached Contents emptied: In a dosing "element" there is a liquid displacement medium, the volume of which is reduced in the dosing "element" by a measuring device in order to absorb the liquid to be dosed. Both liquids are separated from each other by a seal sliding in the dosing "element". The seal must be sufficiently soft so that it can be moved by the displacement medium. The compression of the displacement medium is therefore partially absorbed by the seal, and errors occur during metering, especially in the volume range of a few microliters. Dosing "elements" with very small diameters are also difficult to manufacture according to this OS. They also have the disadvantage that they have to be pre-filled with the compression medium before the dosing process begins and that the liquid to be dosed comes into contact with a surface which was previously wetted with the compression medium.

The same OS shows some other ways of reducing the air cushion between a pipette and a dosing cup to increase dosing accuracy. In none of these proposals is it intended to separate the filled dosing vessel from the measuring device.

OBJECT OF THE INVENTION

With a dosing device, the dosing vessel of which can be filled with the liquid to be dosed and then temporarily separated from the pipette without the dosing vessel emptying in an uncontrolled manner, dosing could be done as precisely as with a capillary piston pipette, and at the same time without carryover as with a piston piston pipette of the DT -PS 12 91 142.

• mit dem ein beliebig genau bestimmtes Flüssigkeitsvolumen in das Dosiergefäß aufgenommen und darin behalten oder in einem oder in mehreren beliebig bemessenen und beliebig genauen Schritten wieder ausgegeben wird,
• bei dem eine Verunreinigung der zu dosierenden Flüssigkeiten durch Rückstände zuvor dosierter Flüssigkeiten vermieden wird
• und bei dem sich das gefüllte Dosiergefäß nicht unkontrolliert entleeren kann, wenn es von der Abmeßvorrichtung getrennt wird.

The inventor has therefore set himself the task of creating a metering device consisting of a measuring device (pipette) and an exchangeable metering vessel,

• with which an arbitrarily precisely determined volume of liquid is taken up in the metering vessel and kept in it or dispensed again in one or more arbitrarily dimensioned and arbitrarily precise steps,
• in which contamination of the liquids to be dosed by residues of previously dosed liquids is avoided
• and in which the filled dosing vessel cannot empty in an uncontrolled manner if it is separated from the measuring device.

The requirements for the dimensional accuracy of the measuring device in The area of the connection to the dosing vessel and the shape accuracy of the entire dosing vessel should be small, the dosing vessels should be inexpensive to dispose of and they should be able to be connected to or detached from the measuring device quickly and without effort, and yet the connection should seal well .

DESCRIPTION

• daß der Innenraum des Dosiergefäßes an den Meßraum der Abmeßvorrichtung anschließbar ist und
• daß sich am Dosiergefäß mindestens zwei Enden befinden, von denen eines (4) an die Abmeßvorrichtung anschließbar ist, wobei sich das Dosiergefäß im Bereich dieses Endes mindestens zeitweise öffnet und eine direkte oder indirekte Verbindung zwischen dem Meßraum der Abmeßvorrichtung und dem Innenraum des Dosiergefäßes geschaffen wird, und sich selbsttätig wieder schließt, wenn das Dosiergefäß von der Abmeßvorrichtung getrennt wird,
• und mindestens ein anderes Ende (5) offen ist oder dauernd oder vorübergehend geöffnet wird, wobei diese Öffnung so eng ist, daß die in das Dosiergefäß aufgenommene zu dosierende Flüssigkeit nicht herausfließt, solange sie im Bereich dieser Öffnung nicht unter einem im Vergleich zur äußeren Umgebung des Dosiergefäßes höheren Druck steht.

The invention solves this problem by

• that the interior of the metering vessel can be connected to the measuring space of the measuring device and
• that there are at least two ends of the metering vessel, one (4) of which can be connected to the measuring device, the metering vessel opening at least temporarily in the region of this end and a direct or indirect connection being created between the measuring chamber of the measuring device and the interior of the metering vessel , and automatically closes again when the metering vessel is separated from the measuring device,
• and at least one other end (5) is open or is opened continuously or temporarily, this opening being so narrow that the liquid to be dosed, which is taken up in the dosing vessel, does not flow out as long as it is not below one in the region of this opening in comparison with the external environment the dosing vessel is at higher pressure.

The measuring device has one or more independent measuring rooms, any number of which are connected to a metering vessel.

• Fig. 1: das Prinzip des Dosierens gemäß der Erfindung,
• Fig. 2: das Zusammensetzen eines Dosiergefäßes, dessen als Behälter ausgebildeter Anteil bereits gefüllt ist,
• Fig. 3: verschiedene Dosiergefäße der Erfindung,
• Fig. 4: das Verketten von Dosiergefäßen zum Zwecke der Probenverteilung,
• Fig. 5: Dosiergefäße, die nach dem Dosiervorgang als Reagenzgefäße weiterverwendet werden, und
• Fig. 6: ein Kupplungsstück zur Aufrüstung einer als Abmeßvorrichtung im Sinne der Erfindung zu verwendenden herkömmlichen Pipette.

The dosing devices of the invention can simplify the workflow in many laboratory analyzes. Their mode of operation is explained below using several drawings. Show it

• 1: the principle of dosing according to the invention,
• 2: the assembly of a dosing vessel, the portion of which is designed as a container has already been filled,
• 3: various dosing vessels of the invention,
• 4: the chaining of dosing vessels for the purpose of sample distribution,
• 5: dosing vessels which are used as reagent vessels after the dosing process, and
• 6: a coupling piece for upgrading a conventional pipette to be used as a measuring device in the sense of the invention.

In the embodiment of the invention shown in FIG. 1, a metering vessel (3a), which is sealed airtight at its upper end with a resilient body (6a) made of silicone rubber, is connected to a measuring device (1), which has a resilient body at its outlet piercing hollow needle (2). The air contained in the metering vessel is sucked out with the measuring device, the liquid of a supply vessel flowing into the metering vessel. The filled dosing vessel is separated from the measuring device after the pressure equalization, and according to the inventive idea, the liquid cannot now flow out of the dosing vessel.

The absorbed liquid is kept in the metering vessel and stored, or defined volumes of a displacement medium are injected into the interior of the metering vessel with the same or with a second measuring device, all at once or in several steps. The same volumes of the liquid to be dosed flow out of the dosing vessel which is open at its lower end. If the volume to be dispensed does not have to be measured precisely, a precisely metering measuring device is not required to dispense the liquid: the interior of the metering vessel is temporarily subjected to an overpressure, or, if an air cushion is present, the surroundings are under a vacuum, which one is required can act for any length of time after the volume to be dispensed.

It is not necessary to keep the dosing vessel connected to the measuring device during dosing breaks. Therefore, a single measuring device can interact with many filled dosing vessels.

In order to prevent contamination of a new sample with previously dosed liquids, a used dosing vessel is exchanged for a fresh dosing vessel before taking up the new sample. In comfortably equipped measuring devices of the invention, the discharge of the metering vessel is facilitated by a lever linkage.

For inaccurately determined dosing volumes, air is used as the displacement medium. If high precision is desired when dispensing the liquid, a displacement medium that is as incompressible as possible in relation to air is used. An essential advantage of the invention is that the air cushion causing the metering error can be removed by repositioning the metering vessel. It is therefore possible to precisely dose a few microliters or even fractions of microliters.

The invention also shows another way of filling the dosing vessel, in which an air cushion is avoided (FIG. 2): the liquid to be dosed is filled into the portion (3m0) of a still incompletely assembled or disassembled dosing vessel (3m1, 3m2) ) and then closes it by z. B. with one end (5), screwed, welded, or the parts soldered together, clamped or joined together by other means, resulting in a complete dosing vessel according to the invention.

Faults due to contamination of the liquid to be dosed with a liquid displacement medium are not to be expected if, for example, to displace aqueous solutions. B. silicone oil is used. With water as a displacement medium for aqueous solutions, elongated thin dosing vessels are used, and both liquids are separated from each other by a small air bubble.

In its simplest design, a metering vessel of the invention (FIG. 3) consists of a hollow vessel (3a, 3b) with two ends (4, 5), one (4) of which has a sealing resilient body (6a; e.g. silicone rubber) and the other (5) has a narrow opening. The measuring device suitable for the metering vessel _' ' i has at its exit a sharp hollow needle (2) with which the resilient body (6a) is pierced. Then the liquid to be dosed is taken up and the dosing vessel is separated from the measuring device again. When the hollow needle is withdrawn, the puncture channel closes by itself. Depending on the volume displaced by the hollow needle in the metering vessel, the level of the liquid in the area of the opening rises by a certain short distance, thereby delaying drying out. The mirror lowers again when the dosing vessel is connected to the measuring device again.

In another metering vessel there is a diaphragm valve (6b), the diaphragm of which is raised by a vacuum created to absorb the liquid. To dispense, the membrane is pierced by the pointed hollow needle of a measuring device.

In a preferred embodiment, the resilient body (6a; e.g. silicone rubber) is held in position by rigid projections (7) of the wall of the metering vessel. A piercing hollow needle can now only slightly deform or deflect the resilient body, and disruptions due to changes in the internal volume of the dosing vessels when piercing with the hollow needle are reduced.

In another embodiment, a channel (8) is additionally provided in a body (9) of low deformability connected to the wall of the metering vessel. This channel sealingly comprises the outlet (2; e.g. a needle) of the measuring device connected to the metering vessel. The inaccuracy of dosing caused by the compressibility of the elastic rubber seal is eliminated.

One embodiment has a membrane (10) which is permeable to air but impermeable to certain liquids, in the case of aqueous solutions, for. B. a water-repellent membrane which is sealingly attached between the projections (7) and the resilient body (6a). It prevents the liquid to be dosed from accidentally entering the measuring device.

In a further embodiment, the resilient body (6a) has an already preformed channel 11, which is closed as long as it is not connected to the outlet (2; e.g. with a blunt hollow needle) of the measuring device.

In a variant of this metering vessel, the channel is designed in such a way that it opens by finger pressure on the resilient body, as a result of which the interior is pressure-balanced with the surroundings and the previously filled liquid flows out of the metering vessel through its hydrostatic pressure to the other open or open end . A manually or mechanically operated valve (12) or a sharp hollow needle, with which the resilient body (6a) is pierced, also serves the same purpose.

A dosing vessel (3i) provided with several outputs is suitable for the simultaneous dispensing of several partial samples.

Another metering vessel (3k) is designed such that all ends are first closed and have the same means as are provided for connecting the metering vessel to the measuring device in the sense of the invention. One end is connected to the measuring device, the other end or the other ends are permanently or temporarily opened by plugging on bidirectional end pieces (13), these openings being so narrow that the liquid to be dosed, which is taken up into the dosing vessel, does not flow out as long as They in the area of these openings are not under one compared to the external environment the dosing vessel is at higher pressure. With this design, after separating the dosing vessels from the measuring device and after removing the bidirectional end piece, samples or reagents are stored long-term because the liquid is particularly well protected against evaporation.

The dosing vessels of the invention are not required to have a particularly high dimensional accuracy in most embodiments because the dosing vessels are not part of the metering device of the metering device which determines the dosing volume, such as the piston and the capillary of a capillary piston pipette, and because the seal between the metering device and the metering vessel is in most cases Cases is not based on the precisely matched fit of the output of the measuring device and the part of the metering vessel connected to this outlet, as in the device of DT-PS 12 91 142, but because the seal in most cases is connected to the metering vessel Measuring device only forms by itself, for. B. in all versions in which a resilient body (6a; z. B. a rubber seal) is pierced by a sharp hollow needle. Accordingly, these dosing vessels are also easy to manufacture and, furthermore, no great force is required to connect them to or remove them from a measuring device.

The invention enables a simultaneous examination of many small samples: the samples are first taken individually into the dosing vessels and then put in at their destination at the same time (with a measuring device having several independent measuring rooms) or very quickly one after the other (measuring device with only one measuring room) Secondary vessels. As a result, the dosing period between the first and the last sample is canceled or it is considerably reduced, and analysis errors caused by evaporation of the dosed samples of different lengths are avoided.

If parts of a sample are to be dispensed to several measuring stations at different times, the entire sample is filled into a dosing vessel and the required tell-tale volumes are then dispensed into secondary vessels. In the case of several samples, it is advisable to arrange the filled dosing vessels in a rack, to hold secondary tubes under the outputs of the dosing vessels and with a measuring device Inject displacement medium into the dosing vessels. If the volumes of the tell samples to be dispensed are not exactly determined, only excess pressure of any duration is applied or one (valve 12) of the ends of the metering vessels is temporarily opened and the liquid is allowed to run out for any length of time. Compared to conventional methods, one test tube and several dosing vessels are saved for each sample, as well as the work involved in replacing the dosing vessels and filling the sample holder into the dosing vessels from the second dispensing step.

According to another method for carryover-free sample distribution, the filled dosing vessels of the invention are coded, taken from their original order and placed in a sequence in accordance with the requirements in a grid which is based on the "sample plate" of the measuring station. Then the partial volumes of the samples to be metered are output to the sample receiving points of the measuring station, one after the other or, if a measuring device having a plurality of independent measuring rooms is available, simultaneously. The dosing vessels are sorted back and are ready for distribution to other measuring stations.

The invention offers an additional possibility of the sample distribution on different measuring stations (Figure 4): At least one metering vessel is designed so that it has another end with a resilient hollow needle (2a) carrying its resilient body (6a) carrying end with which it is connected to another dosing vessel. Several dosing vessels are connected to one another like a chain, an open connection being created for the interior of the dosing vessels, and the liquid to be dosed is filled (injected or sucked in) with the aid of a measuring device (syringe). The capacity of the individual dosing vessels forming the chain and / or the penetration depth of the hollow needles into the dosing vessels are adapted to the intended, if necessary, different volumes of the partial samples. If necessary, the dosing vessels are made in the desired size immediately before filling. This chain technique is also suitable for dividing a sample into several portions. If the portions are to be kept for a longer period of time, preference is given to using dosing vessels (3k) which are closed at all ends and carry at least two resilient bodies which can be pierced. They are joined together for filling with two-directional or multi-directional connecting pieces (13; e.g. hollow hollow needles at both ends).

The dosing vessel can also be used as a reaction vessel (Figure 5). For this purpose, reagents and samples are taken one after the other and reacted in the dosing vessel. This procedure saves pipette tips and test tubes. For the evaluation, the dosing vessel itself is placed in the beam path of a photometer, or its contents are previously filled into a measuring vessel.

By means of intermediate pieces (14; FIG. 6), the metering vessels of the invention can be connected to conventional measuring devices that work according to the most varied of principles.

Claims (10)

1.Dosing device for liquids, which consists of a measuring device 1 (pipette) and a replaceable metering vessel 3a-3m which can be connected to the outlet 2 of the measuring device, and with which an arbitrarily precisely determined volume of liquid is taken up in the metering vessel and retained therein or in one or in several arbitrarily dimensioned and arbitrarily precise steps are output again, in which contamination of the liquids to be dosed by residues of previously dosed liquids is avoided and in which the filled dosing vessel cannot empty in an uncontrolled manner when it is separated from the measuring device,
characterized, that the interior of the metering vessel can be connected to the measuring space of the measuring device and that there are at least two ends of the metering vessel, one of which 4 can be connected to the measuring device, the metering vessel opening at least temporarily in the region of this end and a direct or indirect connection being created between the measuring chamber of the measuring device and the interior of the metering vessel, and closes automatically when the dosing vessel is separated from the measuring device, and at least one other end 5 is open 3a-3i or is opened continuously or temporarily 3k, this opening being so narrow that the liquid to be dosed, which is taken up in the dosing vessel, does not flow out as long as it is not under one in the area of this opening compared to the outside pressure of the metering vessel is higher. 2. dosing vessel 3m1, 3m2 according to claim 1, whose portion 3m0 designed as a container is already filled with the liquid to be dosed before it is finally assembled,
characterized,
that means are available on the parts of the metering vessel that allow a quick and easy assembly. 3. dosing vessel according to claim 1 or 2, characterized in

that at its end connectable to the measuring device there is a resilient body 6a which closes the metering vessel as long as it is not connected to the measuring device, and which is completely or partially displaced by components of the measuring device when the metering vessel is connected to the measuring device, one of which open connection between the measuring chamber of the measuring device and the interior of the metering vessel is created. 4. dosing vessel according to claim 3,
characterized,
that the resilient body 6a consists of a rubber-like material and the displacing component of the measuring device consists of a hollow needle 2 which can be drilled through this material. 5. dosing vessel according to one or more of the preceding claims, which is filled with the liquid to be dosed and partially or completely emptied automatically or by hand without a measuring device,
characterized,
that additional means 12 are present on the metering vessel with which its interior is opened to the outside,
whereby there is a pressure equalization of the interior with the surroundings and the liquid flows out of the metering vessel through its hydrostatic pressure to the or to the other open or opened ends,
or whereby the interior is subjected to a pressure higher than the ambient pressure and the liquid flows to the or to the other open or opened ends from the metering vessel. 6. dosing vessel according to one or more of the preceding claims, characterized in that
that it is pre-filled with reagents. 7. dosing vessel 3k according to one or more of the preceding claims, in which all ends are temporarily closed, and bidirectional end pieces 13,
characterized,
that the ends have the same means 6a, 6b, 7, 8, 9, 10, 11, as are provided for connecting the metering vessel to the measuring device according to one or more of the preceding claims, one end being connected to the measuring device and the other end or the other ends by plugging bidirectional end pieces 13 are opened permanently or temporarily, and these openings are so narrow that the liquid to be dosed, which is taken up in the metering vessel, does not flow out, as long as it is not under one in the area of these openings compared to outside of the metering vessel is at higher pressure. 8. The device and method for distributing a liquid into several portions of the same or different size using the metering vessels according to one or more of the preceding claims,
characterized, that the metering vessels, in addition to the end 4 which can be connected to the measuring device, have at least one end which has means 2a, as are provided for the measuring device for connection to the metering vessels according to one or more of the preceding claims, that the interiors of several dosing vessels are connected to one another via these ends and that the liquid to be distributed is sucked or injected into the assembly, the partial volume provided for each metering vessel being determined by a targeted variation in the capacity of the individual metering vessels or by other means. 9. Device and method for using a metering vessel according to one of the preceding claims as a reagent vessel,
characterized,
that reagents and samples are taken one after the other into the dosing vessel and reacted therein. 0. dosing device and intermediate pieces 14,
characterized,
that any conventional measuring device interacts with one or more dosing vessels according to one or more of the preceding claims and the dosing vessels are connected to one another by suitable intermediate pieces 14.

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