NL8802779A - METHOD AND APPARATUS FOR DOSING A FLUID SUBSTANCE - Google Patents

Description

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* G PEM / MB / Kone18

Method and device for dosing a flowing substance

The present invention relates to a method of dosing a fluid, such as a liquid or a gas. The invention particularly relates to the dosing of substances in small quantities in connection with wet chemical analyzes and the like under laboratory conditions.

A commonly used solution for dosing small amounts of fluids is an injection syringe, which consists of a cylinder and a piston moving inside it, which can suck up a certain amount of fluids and dose them at the desired destination.

For manual dosing, the syringe is a convenient and accurate tool, but its high cost limits its applicability in larger systems, whether partially or fully automated.

One of the devices currently used for transferring and dosing liquids is the peristaltic pump, which is usually formed by a rotatable roller, which is mounted against a cylindrical surface and a flexible hose placed between the roller and the cylindrical surface , which moves the fluid in the hose. The cylindrical surface of the roller is provided with protrusions equally spaced so that the hose is squeezed flat through each protrusion so that the liquid in the hose is distributed to doses of a certain volume between the protrusions . As the roller rotates, the doses of fluid are pushed forward through the protrusions in the hose. The disadvantages of the device are its inaccuracy and a slight fluctuation in the liquid flow due to small inverse flows of the fluid which occur every time a protrusion is detached from .8802779 <P9ΨΤΤ1 -2- contact with the snake.

According to another dosing method, the fluid is passed through thin tubes to a space of a certain size, in which a dose of the fluid is confined by freezing it at certain points at both ends of the dosing space. This solution, which is described in Finnish Patent Publication 57850, is designed for use in an analyzer using only this type of frozen plugs to control liquid flow. The solution is not practical for use in a simple measuring and analysis device.

The object of the present invention is to provide a simple solution for the dosing of fluids, which can be used extensively in various systems, in particular for the dosing of liquids, but also of gases. The invention is characterized in that the substance is passed into a branched pipe system where it is passed through an input branch to a branch point connected to two or more extension branches, the flow past the branch point into one of the extension branches. is guided, that the flow is stopped and that the part of the substance which has entered the extension branch is separated from the part remaining in the input branch by flowing an auxiliary substance into one of the branches or into a second extension branch, whereby the auxiliary substance is immiscible with the substance to be metered, so that one of the parts is diverted away by the flow of the auxiliary substance, the two parts being separated by an interface appearing at the branching point of the pipe branches.

The basic idea of the invention is to make use of the surface tension between the substance to be metered and the admixture that cannot be mixed with it. Since the branches of the piping system have capillary dimensions at least in the region of the branching point 35, the surface tension between the immiscible substances forms an interface at the branching point, an interface of the same shape being at the same point at .8802779 -3 * * is formed in the pipe. This explains the accuracy of the dosage achieved by the invention.

The main field of application of the invention is found in chemical wet analysis instruments, which involve dispensing a liquid, usually an aqueous solution. The liquid immiscible adjuvant may be a gas, for example, air or other immiscible water-miscible fluid, for example, oil or a similar organic fluid.

A preferred embodiment of the method according to the invention is characterized in that the substance to be dosed is guided in a system of branched pipes, where it is passed through an input branch with a determined dosage volume to a branch point connecting two or more extension branches. that the fabric is passed along the branching point into one of the extensions, that the flow is interrupted to prevent reverse flow of the fabric into the input branch, and that the portion of the fabric that has entered the extension branch is removed by flowing an auxiliary substance which is immiscible with the substance to be dosed through one of the extension branches such that the part is diverted away by the flow of the auxiliary substance, so that the interface of the part remaining behind in the input branch is at the branching point the end of the input branch. One of the extension branches of the piping system may include a pump which both draws the substance to be dosed through the inlet branch and, by pumping the excipient in the opposite direction, the portion of the substance passing through the branching point into the extension branch has moved.

Another preferred embodiment of the method according to the invention is characterized in that it uses a system of branched pipes, wherein the input branch at a branch point is split into a main branch and a side branch, and in which the main branch is connected at a second branch point. other side branch, that • 8802779 -4-% initially an additive which is not miscible with the material to be metered is led into at least the two side branches, that the substance to be metered is then introduced into the input and main branches of the system in such a way that at least the part of the main branch, which is delimited by the branching points of the two side branches, is filled with the substance, whereby at the branching points interfaces are formed between the substance to be dosed and the auxiliary substance present in the side branches, which input branch as at a point before the first branch-10 point and in the main branch at a point after the second branch-point the flow of the cool is interrupted, and finally the adjuvant is passed through the side branches to remove the portion of the portion of the fabric present in the main branch between the interfaces at the two branch points. The part of the main branch, which is bounded by the branching points of the two side branches, thus forms the space of a certain volume, in which the dose is formed.

The invention also relates to an apparatus for applying the above-described dosing method. The device comprises, as essential parts, a system of branched pipes, which is formed by an inlet branch and one or more side or extension branches, which are connected at one or more branch points to the inlet branch or extensions thereof, and the necessary means for causing matters of the desired flow of the substance to be dosed and the auxiliary substance in the pipes. Detailed features of the device are described in the claims below (claims 7-10).

As already mentioned, the invention is suitable for use in wet chemical analysis devices. Such devices include analyzers used in clinical and immunological chemistry to produce medical diagnoses of samples of substances, such as blood or urine, taken from a patient. The device can also be used for chemical analyzes of samples, mainly of water, that come from the environment.

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Next, the invention will be described in more detail with the help of examples, referring to the accompanying drawings, in which: Figs. 1-5: illustrate various steps of the fluid treatment, including dosing the flowing material as provided by the invention? Figures 6-7: show two different variants of a branch point of pipes as used in the dosing device of the invention; Fig. 8-10 show different steps of a second embodiment of the dosing method according to the invention; 11-14: show different steps of a third embodiment of the dosing method according to the invention? and FIGS. 15-17 show different steps of a fourth embodiment of the metering working wedge according to the invention, wherein the piping input branch branches to five extension branches at the same branching point.

Pig. 1-5 show a process in which the method of the invention is used to separate a dose of a given volume from a liquid reagent, which is mixed with a sample in a sample cell and then transferred to a photometer for a measurement. The device used is constituted by a system of branched pipes, wherein the input pipe 1 branches at a T-shaped branch point 2 into two extensions 3, 4. Branch 3, which is a direct extension of the input pipe 1, is provided with a pump 5 , and the other, perpendicular extension branch 4 is provided with a valve 6. The input branch 1 is also provided with a valve 7. In front of the branch point 2, the inlet pipe 1 branches to two side branches 8, 9, one of which goes to the sample cell 10, and the other of which leads to the photometer 11. Each side branch 8, 9 is provided with a valve 35 12, 13.

Fig. 1 shows an initial situation in which a liquid reagent flows through the pump 5 through the input branch 1 into. 8802779 * «r · -6- the system has been sucked so that the liquid column in the pipe has moved beyond branch point 2 to the point indicated by reference number 10. During suction phase, valve 7 in inlet branch 1 is open while the other 5 valves 6, 12, 13 are closed. In the situation shown in Fig. 1, the suction is interrupted and the valve 7 in the infeed branch is closed. Subsequently, the valve 6 is opened in the extension, and, as shown in Fig. 2, air is blown through the reverse rotating pump 105 through the extension branches 3, 4, so that the air flow passes the part 15 of the flowing removes dust that has progressed beyond branch point 2 during the suction phase. The interface of the liquid column in the input pipe forms precisely at the end of the input branch 1 15 at the branch point 2. Thus, a dose of flowing substance of a defined volume is enclosed in the input branch 1.

Furthermore, as shown in Fig. 2, the sample cell 10 comprises the sample 16 of a liquid or a solid to be diagnosed. Fig. 3 shows the next step, in which the valve 6 in the extension branch 4 is closed, the valve 12 in the side branch 8 leading to the sample cell 10 is opened and the dose of reagent contained in the inlet branch 1 is opened into the sample cell is pressed by an air flow produced by the pump 5. The sample in the sample cell 10 is preferably dissolved in the reagent to produce a solution 17, which is then diagnosed. As shown in Fig. 4, the solution is drawn by the pump 5 back to the inlet pipe 1 and its direct extension 3, so that the sample cell 10 and the lateral branch 8 leading to it are emptied. When the liquid column in the pipe extends to point 18, the suction is interrupted, the valve 12 in the side branch 8 leading to the sample cell 10 is closed, the valve 13 in the side branch 9 leading to the photometer 11 is opened, and, As shown in Fig. 5, the solution is passed through the pump 5 to the photometer for a measurement. After the measurement, • 8802779 -7- the solution is drained to an extension of the side branch 9.

Fig. 6 and 7 show two alternative types of branch points 2 for the connection of the pipes. In any case, the flowing substance to be dosed fills the input branch 1 such that the interface 19 appears exactly at the end of the input branch at the branch point 2.

In the embodiment shown in FIGS. 8-10, the dosing equipment consists of a branched pipe system in a generally H-shaped configuration, with the inlet pipe 20 branching at a first branching point 21 into a main branch 22, which is inclined at an angle of 90 ° is positioned relative to the inlet branch 20, and a side branch 23, which forms a direct continuation of the input branch 20. The main branch 22 is provided with another branch point 24, the main branch itself being bent at an angle of 90 "(the part of the main branch beyond the branch point is indicated by reference number 25), and connected to another side branch 26, which is also placed at an angle of 90 ° The inlet branch 20 and the first side branch 23 are provided with pumps 20 27, 28 and each of the four branches 20, 23, 25, 26 is provided with a valve 29-32.

During the dosing process, the substance to be dosed is a liquid and the auxiliary substance is another liquid, which is chosen such that the two liquids are not miscible. At the initial state shown in Figure 8, the entire system is filled with the auxiliary liquid pumped by the pumps 27, 28, after which the valves in the side branches 23, 26 are closed. Then, as shown in Fig. 9, the valves 29, 32 are opened and, using the pump 27 30, the input branch 20 and the main branch 22, 25 are filled with the substance to be metered, with between the substance to be metered and the auxiliary material at the pipe branch points 21, 24 precise interfaces 33, 34 are formed. After the pumping is finished and the valves 29, 32 in the inlet and main branches are closed, the valves 30, 31 in the side branches 23, 26 are opened, and, as shown in Fig. 10, the pump 28 in the side branch 23 used to produce a flow of auxiliary liquid, which carries away that portion of the dispensable substance trapped in the main branch between the two junctions. The dose thus obtained, which flows with the auxiliary liquid, is indicated in Fig. 10 by reference neuramer 37.

FIG. 11-14 illustrate an embodiment in which the dosing operation has been temporarily or locally removed using the dosing principle of the invention. The system of pipes, consisting of a main branch 39 and an input branch 10 connected thereto at branch point 40 (the part of the main branch beyond the branch point is indicated by reference number 42) is connected to a dosing device 38, which has sufficient accuracy, for example a syringe . Each branch is provided with a valve 43, 44 and is connected to a pump or the like device (not shown).

In the initial situation shown in Fig. 11, part of the fluid to be dosed has been drawn through the inlet branch 41 into the main branch 43, such that the liquid flow at the branch point 40 is rotated in the direction from the dosing device 38. At the end of this suction phase, the valve 44 in the inlet branch is closed, after which, as shown in Fig. 12, using the dosing device 38, another liquid, which in this case acts as an auxiliary liquid, is sucked into the main branch 39, 25 42. The flow of the auxiliary liquid now removes that part of the liquid to be dosed which has entered the main branch 42, so that at the end of the input branch 41 at the branch point 40 an interface is created between the two liquids. Subsequently, the valve 43 in the main branch is closed and the valve 44 in the input branch is opened, after which a certain amount of auxiliary liquid is dosed through the dosing device 38, so that, as in fig.

13, an equal amount of the liquid to be metered flows simultaneously through the input branch 41 past the branch point into the main branch 39. This last dose of liquid can now be directed to the desired destination using the dosing device which pushes out the do-8802779% sis by pumping auxiliary liquid through the main branch 39,42. Fig. 14 shows a situation where the valve 44 at the inlet branch is closed and a dose of 46 liquid is forced through the auxiliary liquid through the main branch 39 to the dosing device 38.

Fig. 15-17 show a set of pipes designed to be used in another embodiment of the invention. In this case, the inlet branch 47 at a branch point 48 is connected to five extension branches 49-53, 10 each of which is provided with a valve 54.

In the initial situation shown in Fig. 15, each of the branches comprises a different liquid. The input branch 47 contains the substance to be dosed, which now flows directly via the branch point 48 into the extension branch 51, where flow 15 is stopped, for example by closing the valve 54 in this branch. The purpose of this operation is to ensure that the inlet pipe is filled with the liquid to be metered up to branch point 48. After this, as shown in Figure 16, the valve 54 in the adjacent extension branch 52 is opened and a certain amount of the liquid to be metered is forced to flow to this extension. The input branch 47 may be connected, for example, to a dosing syringe, in which case this solution involves a removal dosing operation similar to that according to the procedure shown in FIG.

11-14 illustrated embodiment. After the flow of the substance to be dosed has stopped, the valve 54 in the input branch 47 is closed, after which the dose in the extension branch 52 can be further moved by means of another liquid obtained from a different extension, and which as an auxiliary substance serves. Fig. 17 shows a situation where the dose 55 is removed from extension branch 52 by the flow of an adjuvant from extension 50.

With regard to the dosing device shown in Figs. 15-17, it should be noted that in principle each of the extension branches 49, 53 connected to branch point 48 can be chosen as the input branch, in which case the substance to be dosed is the substance which is present in the chosen branch.

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This solution is useful provided that the substance to be dosed must not be miscible with the excipient substance.

It will be apparent to those skilled in the art that the various embodiments of the invention are not limited to the examples described above, but rather are varied within the scope of the following claims.

0.8802779

Claims (11)

Method for dosing a flowing substance, characterized in that the substance is led into a system of branched pipes, where it passes through an input branch (1, 20, 41, 47) to a branch point (2, 21, 40 , 48) 5, which is connected to two or more extension branches (3-4, 22-23, 39, 42, 49-53), directs the current past the branch point into one of the extension branches (3, 22, 39, 52), the flow is caused to be stopped and the part (15, 37, 46, 55) of the substance, which has entered the extension branch 10, is separated from the part remaining in the input branch by an auxiliary substance flowing in one of the branches (3, 22, 39, 52) or in a second extension branch (4, 23, 42, 50), in which the auxiliary substance is not miscible with the substance to be dosed, so that one of the parts the flow of the adjuvant is diverted, the two parts being separated by an interface (19, 35, 45) appearing at the branch point of the pipe branches. 2. A method according to claim 1, characterized in that the substance to be dosed is a liquid and that the auxiliary substance is a gas. Method according to claim 2, characterized in that the substance to be dosed and the auxiliary substance are immiscible liquids. Method according to one of Claims 1 to 3, 25, characterized in that the substance to be dosed is introduced into a system of branched pipes, where it is passed through an input branch (1) with a determined dosage volume, which branch point is connects two or more extension branches (3, 4), that the fabric is guided past the branch point into one of the extensions, that the flow is interrupted to prevent reverse flow of the substance into the feed branch, and that the part of the substance which has entered the extension branch, is removed by flowing an admixture immiscible with the substance to be metered through one of the extension branches, such that the part of the substance is mixed with the flow of the auxiliary substance. so that the boundary surface (19) of the part remaining in the input branch is at the branch point at the end of the input branch. Method according to claim 4, characterized in that the substance to be dosed is drawn into the system of pipes by using a pump (5) placed in one of the extension branches (3) and in that the same pump is used for removing the part of the substance that has been fed from the feed branch (1) past the branch point (2) into the respective extension branch by operating the pump in a direction opposite to that for the suction operation. A method according to any one of claims 1 to 3, characterized in that it uses a system of branched pipes, wherein the input branch is split at a branch point into a main branch (22) and a side branch (23), and wherein the main branch (22, 25) is connected at a second branch point (24) to another side branch (26), that initially an additive which is not miscible with the substance to be dosed is led into at least the two side branches, that the substance to be dosed then fed into the input and main branches of the system such that at least the portion of the main branch bounded m by the branch points of the two side branches is filled with the substance, with interfaces (33, 34) at the branch points ) is formed between the substance to be dosed and the adjuvant present in the side branches, that the flow of the substance to be dosed is formed both in the feed branch and at a point before the first branch point and in the main branch at a point after the second branch point. w is interrupted, and that finally the adjuvant is passed through the side branches to remove the part of the substance present in the main branch between the interfaces (35, 36) at the two branching points. Device for carrying out the method according to claim 4 or 5, characterized in that the. device is constituted by a system of branched pipes, comprising. 8802779 4. -13- an input branch (1) of a given dosage volume, which is bounded at one end by a branch point (2) connecting one or more extension branches (3f 4), and means (5) for such introduction into the piping the substance to be dosed, that the substance will flow past the branching point and means for removing the part (50) of the substance, which can be passed through the extension branches, which can be mixed by a non-dosable substance, through the extension branches. the branching point has flowed into an extension branch, and that the input branch is provided with at least one valve (7) to avoid reverse flow of the substance to be metered into the input branch during discharge of the part. 8. Device according to claim 7, characterized in that the device comprises a pump (5), which is placed in one of the extension branches (3) of the system of pipes, such that the pump can be used for both sucking the substance to be dosed into the pipe as for removing the part (15) of the substance which extends beyond the branch point in the respective extension branch. 20 has arrived. Device for carrying out the method according to claim 6, characterized in that the device is formed by a system of branched pipes, wherein the input branch (20) branches at a branch point (21) into a main branch (22) and a side branch (23), and where the. main branch (22, 25. further connected at a second branch point (24) to another side branch (24) and provided with means (27, 28) for feeding at least into the side branches of the system one to be dosed substance immiscible adjuvant, and means (27) for feeding the substance to be dosed at least into the input branch of the system and further into the main branch such that at least the part of the main branch delimited by the two branching points the fabric is being filled, and the valves (29, 32) are arranged in the feed branch before the first branch and in the main branch after the second branch to prevent flow of the substance to be dosed into these branches, so that the intermediate the two branching points of the substance can be removed by the flow of an adjuvant flowing through the side branches. Device according to any one of claims 7-9, 5, characterized in that the pipe branches (1, 3, 4) have a limited diameter in the region of the branch point (2). 11. Apparatus according to any one of claims 7-10, characterized in that it forms part of an analyzer used for wet chemical analyzes, and in particular a clinical analyzer. 0 t. 8802779