FR2623182A1 - METHOD AND DEVICE FOR DOSING A FLUID SUBSTANCE - Google Patents

Abstract

Method and device for metering a fluid using a set of connected pipes in which an inlet branch 1 leads to a junction 2 connected to two or more branches 3, 4. The substance to be dosed is allowed to flow past of the junction, in one of the branches 3 where the flow is stopped. The fraction of substance, which has entered the branch, is separated from the fraction remaining in the input branch, by circulation of an auxiliary substance immiscible with the substance to be dosed in one of the branches 3 and a second branch. 4 so that one of the fractions 15 is entrained by the auxiliary substance. The two fractions are separated by a surface generated by surface tension at the junction of the branches. The accuracy of the assay is due to the fact that a separation surface can be generated repeatedly in the same place. The invention is particularly applicable to wet chemical analyzers in which the substance to be determined is a fluid, generally an aqueous solution, and the auxiliary substance can be a gas, for example air, or another non-fluid miscible with water.

Description

The present invention relates to a method for the determination of a substance

  fluid such as a liquid or a gas. The invention relates particularly to the dosing of substances in small amounts, in conjunction with wet chemical analyzes, etc., in laboratories. A typical solution for dosing small amounts of fluid is to use a syringe comprising a cylinder in which a piston moves, which can draw up a certain amount of fluid and dose it and then expel it to the desired destination. For manual dosing, the syringe is a convenient and precise instrument but its high cost limits its possibility of application in larger systems, partially or completely automatic. One of the devices currently used for transferring and dosing fluids is the peristaltic pump which typically consists of a rotating roller, applied against a cylindrical surface, and a flexible tube 20 placed between the roller and the cylindrical surface, the fluid advancing in the flexible tube. The cylindrical surface of the roller has projections located at an equal distance from each other, the flexible tube being pinched flat by each projection so that the fluid contained in the flexible tube is divided into doses of a certain volume between the projections. When the roller rotates, the doses of fluid are pushed forward into the flexible tube by the projections. The drawbacks of the device are its imprecision and a slight fluctuation in the flow of fluid which results from slight reversals of fluid flow occurring each time a sail moves away from contact with the tube. In another dosing method, the fluid is introduced through thin tubes into a space of a given size, in which a dose of the fluid is trapped by freezing the tubes at certain points at the two ends. mites of the dosing space. This solution, which is described in patent FI 57850, is intended for use in an analysis device which exclusively employs this type of freezing closure to control the flow of fluid. The solution is not suitable for use in simple measurement and analysis equipment. The objective of the present invention is to provide a simple solution for the metering of fluid substances, which can be widely applied in various systems, in particular for the metering of liquids but also of gases. The invention is characterized in that the substance is introduced into a set of connected pipes where it advances in the input branch, to a point of referral where two or more connections are connected; in that the fluid is allowed to flow beyond the point of referral, in one of the branches; in that the flow is stopped and in that the fraction of substance which has entered the branch is separated from the fraction remaining in the input branch by circulation of an auxiliary substance in one of these branches or a second branch, said auxiliary substance being of a type which does not mix with the substance to be dosed, so that one of the fractions is entrained by the circulation of the auxiliary substance, the two fractions being separated by a boundary surface appearing at the point of referral. The basic idea of the invention is to use the surface tension between the substance to be dosed and the auxiliary substance immiscible with it. As the connections of the pipe assembly, at least in the region of the junction, are of capillary dimensions, the surface tension between the immiscible substances 2623182 3 generates a separation surface at the point of referral, a surface of separation of the same shape being always generated at the same point in the pipe. This explains the metering precision provided by the invention. The main field of application of the invention is that of instruments for wet chemical analysis comprising the determination of a fluid, usually an aqueous solution. The auxiliary substance immiscible with the fluid may be a gas, for example air, or another fluid immiscible with water, for example oil or a similar organic fluid. A preferred embodiment of the method of the invention is characterized in that the substance to be dosed is introduced into a set of branched pipes where it advances in an inlet branch having a determined dosing volume up to at a branch or switch point where two or more branches connect; in that the substance is allowed to flow past the point of referral, in one of the branches; in that the flow is interrupted so as to prevent a back flow of the substance in the inlet branch; and in that we remove the fraction of the substance which entered the branch, by

  circulation of an auxiliary substance, immiscible with the substance to be dosed, in one of the branches in such a way that said fraction is caused by the circulation of the auxiliary substance, so that the separation surface of the fraction remaining in the input branch is located at the point of referral, at the end of the input branch. One of the pipe connections can be provided with a pump which sucks the substance to be dosed in the input branch and, in addition, by pumping the auxiliary substance in the opposite direction, discharges the fraction of the substance who advanced 35 past the point of referral, into the branch. Another preferred embodiment of the method of the invention is characterized in that it uses a set of connected pipes in which the inlet branch divides, at the location of a junction, in a side branch and a main branch, to which another side pipe is connected at the location of a second junction; in that we first introduce an auxiliary substance, immiscible with the substance to be dosed, at least in the two side pipes; in that the substance to be dosed is then introduced into the inlet branch and the main branch of the pipe assembly in such a way that at least the part of the main branch which is delimited by the junctions of the two lateral branches is filled with said substance, separation surfaces being generated at the junctions between the substance to be dosed and the auxiliary substance present in the lateral branches; in that the flow of the substance to be metered is interrupted both in the inlet branch, at a point situated before the first junction, and in the main branch at a point situated after the second junction; and in that the auxiliary substance is finally circulated in the lateral branches so as to evacuate the part of substance contained in the main branch between the separation surfaces at the two junctions. The part of the main branch which is delimited by the junctions of the two lateral branches thus constitutes the determined volume space in which the dose is formed. The invention also relates to a device for implementing the dosing method described above. The device comprises, as essential parts, a set of branched pipes comprising an inlet branch and one or more lateral or extension branches 35 connected to the inlet branch or its extension, to the location of one or more junctions, and the means necessary to establish the desired flow of the substance to be dosed and of the auxiliary substance in the pipes. Detailed features of the device are given in the appended claims 7 to 10. As already indicated, the invention is suitable for application in chemical analysis apparatus in the wet phase. Such devices are, for example, analyzers used in clinical and immunological chemistry to provide medical diagnostics of samples of substances such as blood or urine taken from a patient. In addition, the apparatus can be used for chemical analysis of samples, mainly of water, from the environment. In addition to the foregoing provisions, the invention also comprises other provisions which will emerge from the description which follows. The invention will be better understood with the aid of the additional description below, which refers to the appended drawings in which: FIGS. 1 to 5 illustrate different stages of a fluid handling process comprising a dosing ge of the fluid according to the invention; Figures 6 and 7 show two different types of a pipe joint used in the metering device according to the invention; FIGS. 8 to 10 illustrate different stages of a second embodiment of the assay method according to the invention; Figures 11 to 14 illustrate different stages of a third embodiment of the assay method according to the invention; and Figures 15 to 17 illustrate different stages 35 of a fourth embodiment of the metering method 2623182 6 according to the invention, in which the input branch of the pipe assembly is divided into five connections to the same junction. It should be understood, however, that these 5 drawings and the corresponding descriptive parts are given solely by way of illustration of the subject of the invention of which they do not in any way constitute a limitation. FIGS. 1 to 5 illustrate a method in which the invention is applied to the separation, from a liquid reagent, of a dose of a defined volume which is mixed with a sample in a sample cell tillonnage and then transferred to a photometer or a measuring instrument. The device used includes a

  15 appears to be connected or branched pipes, in which an inlet pipe 1 divides into two branches 3,4 at the location of a T-shaped junction 2. Branch 3, which is an extension direct from the inlet pipe 1, comprises a pump 5, and the other perpendicular connection 20 4 comprises a valve 6. The inlet branch 1 also comprises a valve 7. Before the junction 2, the inlet pipe - entry 1 has two lateral connections 8, 9, one of which leads to the sample cell 10 and the other to a photometer 11. Each lateral connection 8, 9 comprises a valve 12, 13. FIG. 1 illustrates an initial situation, in which a fluid reagent has been sucked by the pump 5 into the circuit, via the inlet branch 1, so that the column of fluid in the pipe has passed the junction 2 and has reached the point indicated by the reference 14. During the suction phase, the valve 7 of the input branch 1 is open, while the other valves 6,12,13 s have closed. In the state shown in Figure 1, the suction is interrupted and the valve 35 7 of the inlet branch is closed. Then, the valve 6 of the connection is opened 2623182 7 and, as shown in FIG. 2, air is blown by the pump 5, turning in the opposite direction, in the connections 3.4, so that the circulation of air entrains the fraction of fluid 5 which has exceeded junction 2 during the aspiration phase. The separation surface of the fluid column in the inlet pipe is then established exactly at the end of the inlet branch 1, at the location of the junction 2. As a result, one traps a dose of fluid of a volume defined in the inlet branch 1. On the other hand, as shown in FIG. 2, the sampling cell 10 contains a sample 16 of a fluid or of a solid substance to be analyzed for diagnosis. FIG. 3 illustrates the following stage, in which the valve 6 of branch 4 is closed, the valve 12 of lateral branch 8 leading to the sampling cell 10 is open, and the dose of reagent which has been trapped in the branch inlet 1 is pushed upward into the sample cell by an air circulation generated by the pump 5. The sample contained in cell 10 is preferably allowed to dissolve in the reagent, to produce a solution 17 which is then analyzed. As shown in FIG. 4, the solution is sucked by the pump 5, 25 back into the inlet pipe 1 and its direct extension 3, so that the cell 10 and its lateral connection 8 are emptied. When the column of fluid in the pipe extends to a point 18, the suction is stopped, after which the valve 12 of the side branch 8 leading to the sampling cell 10 is closed. opens the valve 13 of the lateral connection 9 leading to the photometer 11 and, as shown in FIG. 5, the pump 5 pushes the solution into the photometer, to take a measurement. After the measurement, the solution is evacuated in an extension of the lateral connection 9. 2623182 8 Figures 6 and 7. show two alternative embodiments of the junction 2 for the connection of the pipes. In each case, the fluid to be metered fills the inlet branch 1 in such a way that the separation surface 19 is formed exactly at the end of the inlet branch, at the location of the junction 2. In the embodiment illustrated in FIGS. 8 to 10, the metering device comprises a set of pipes connected in a general H-shaped arrangement 10, in which the inlet pipe 20 branches off at a first junction 21 , in a main branch 22, which is perpendicular to the inlet branch 20, and a lateral branch 23 constituting a direct extension of the inlet branch 20. The main branch 22 has another junction 24 at the place where the main branch is itself bent at 90 (the part of the main branch beyond the junction is unraveled by reDère 25) and is connected to another lateral branch 26 also directed at a right angle. The input branch 20 and the first lateral connection 23 comprise pumps 27, 28 and each of the four connections 20, 23, 25, 26 comprises a valve 29, 30, 31, 32. In this dosing method, the substance to be dosed is a fluid and the auxiliary substance is another fluid which is chosen so that the two fluids are not miscible. In the initial state shown in FIG. 8, the whole assembly is filled with the auxiliary fluid which is introduced by the pumps 27, 28, after which the valves of the lateral connections 23, 26 are closed. Then, as shown in FIG. 9, the valves 29, 32 are opened and, by means of the pump 27, the inlet branch 20 and the main branch 22, 25 are filled with surfaces to be metered. of separation 35 33,34 then being generated between the substance to be dosed and

  2623182 9 the auxiliary substance, at the junctions 21, 24 of the pipes. After the end of pumping and the closing of the valves 29,32 of the inlet branch and the main branch, the valves 30,31 of the lateral branches 23,26 are opened and, as shown in the figure 10, the pump 28 of the lateral branch 23 is used to generate an auxiliary fluid circulation which causes the fraction of the substance to be metered which was trapped in the main branch between the two junctions. The dose thus obtained and which circulates with the auxiliary fluid is indicated by the reference 37 in FIG. 10. FIGS. 11 to 14 illustrate an embodiment in which the dosing operation is temporarily or locally displaced, in using the assay principle of the invention. The set of pipes, comprising a main branch 39 and an inlet branch connected to this branch at the location of a junction 40 (the part of the main branch beyond the junction being designated by the reference 42 ), is connected to a metering device 38 capable of sufficient accuracy, for example a syringe. Each branch has a valve 43,44 and is connected to a pump or to a similar device (not shown). In the initial situation shown in FIG. 11, part of the fluid to be metered was sucked, via the inlet branch 41, into the main branch 43 in such a way that the flow of fluid changes direction at the junction 40 - and moves away from the metering device 38. At the end of this suction phase, the valve 44 of the inlet branch is closed, after which, as shown in Figure 12 and by means of the metering device 38, another fluid which acts in this case as an auxiliary fluid is drawn into the main branch 39,42. The flow of the auxiliary fluid then causes the metering fluid which has entered the main branch 42 to break up, so that a separation surface between the two fluids is created at the end of the branch. inlet che 41, at the junction 40. Next, the valve 43 of the main branch is closed and the valve 44 of the inlet branch is opened, after which a certain amount of the auxiliary fluid is metered by the metering device 38 so that, as shown in Figure 13, an equal amount of the fluid to be metered flows at the same time through the inlet branch 41 beyond the junction, into the main branch 39. This last dose of fluid can now be directed to the desired destination, by means of the metering device which pushes the dose outwards by pumping auxiliary fluid into the main branch 39,42. FIG. 14 illustrates a situation in which the valve 44 of the inlet branch is closed and a dose 46 of fluid is pushed by the auxiliary fluid into the main branch 39 towards the metering device 38. FIGS. 15 to 17 illustrate a set of pipes intended for use in another embodiment of the invention. In this case, the input branch 47 is connected, at the location of a junction 48, to five connections 49-53 each of which comprises a valve 25 54. In the initial situation shown in FIG. 15, each of connections contains a different liquid substance. The inlet branch 47 contains the metering substance, which flows beyond the junction 48 directly in the extension 51 where the flow is stopped, for example by closing the valve 54 of this connection. The purpose of this operation is to ensure that the inlet pipe to junction 48 is full of dosing liquid. After this operation, as shown in FIG. 16, the valve 54 of the adjacent connection 52 is opened so that a certain quantity of the liquid to be dosed flows into this connection. The input branch 47 can be connected for example to a dosing syringe and in this case this solution constitutes a displaced dosing operation similar to that of the embodiment of FIGS. 11 to 14. After stopping the flow of the substance to be dosed, the valve 54 of the inlet branch 47 is closed, after which the dose contained in the branch 52 can be driven further by means of another liquid coming from another branch and acting as an auxiliary substance. FIG. 17 illustrates a situation in which the dose 55 is displaced from branch 52 by the flow of the auxiliary substance coming from branch 50. As regards the dosing device shown in FIGS. 15 to 17, it should be noted that, in principle, any of the branches 49-53 connected to the junction 48 can be chosen as the input branch, the substance to be dosed being in this case the substance contained in the chosen branch. This solu-

  20 is usable provided only that the substance to be dosed is not miscible with the substance serving as an auxiliary substance. As is apparent from the above, the invention is in no way limited to those of its modes of implementation and application which have just been described more explicitly; on the contrary, it embraces all the variants which may come to the mind of the technician in the matter without departing from the framework or the scope of the present invention. 2623 182 12

Claims (11)

Claims   1. Method for dosing a fluid substance, characterized in that the substance is introduced into a set of connected pipes where it advances in an input branch (1,20,4i, 47) up to a junction (2,21,40,48) which is connected to two or more branches (3-4,22-23,39,42,49-53); in that the fluid is allowed to flow beyond the junction, in one of the branches (3,22,39,52); in that one stops the flow and in that one separates the fraction (15,37,46,55) 10 of substance, which entered the branch, from the fraction which remains in the branch of inlet, by circulation of an auxiliary substance in one of said branches (3,22,39,52) or a second branch (4,23, 42,40), said auxiliary substance being not misci - 15 ble with the substance to be dosed, so that one of the fractions is entrained by the circulation of the auxiliary substance, the two fractions being separated by a separation surface (19,35,45) appearing at the connection junction. 20   2. Method according to claim 1, characterized in that the substance to be dosed is a liquid and in that the auxiliary substance is a gas.   3. Method according to claim 1, characterized in that the substance to be assayed and the auxiliary substance are immiscible liquids.   4. Method according to any one of claims 1 to 3, characterized in that the substance to be dosed is introduced into a set of connected pipes where it advances in an inlet branch (1) having a metering volume determined up to a junction which is connected to two or more branches (3,4); in that the substance is allowed to flow beyond the junction, into one of the branches; in that the flow is interrupted so as to prevent a flow of the substance 2623182 13 back into the inlet branch; and in that the fraction (15) of the substance which has entered the branch is removed by circulation of an auxiliary substance, immiscible with the substance to be dosed, in one of the branches in such a way that said fraction is entrained by the circulation of the auxiliary substance, so that the separation surface (19) of the fraction remaining in the input branch is located at the junction, at the end of the 10 input branch.   5. Method according to claim 4, characterized in that the substance to be dosed is sucked into the set of pipes by means of a pump (5) placed in one of the connections (3); and in that the same pump is used to move the fraction of substance, which has advanced from the input branch (1) and beyond the junction (2), in the branch concerned, by operation pump opposite to the one used for suction. 20   6. Method according to any one of claims 1 to 3, characterized in that it uses a set of connected pipes in which the inlet branch divides, at the point of a junction, into a main branch (22) and a lateral branch (23) and in which the main branch (22,25) is also connected, at the place of a second junction (24), to another lateral branch ( 26); in that an auxiliary substance is first introduced, immiscible with the substance to be dosed, at least in the two lateral connections; in that the substance to be dosed is then circulated in the inlet branch and the main branch of the pipe assembly in such a way that at least the part of the main branch which is delimited by the junctions of the two lateral branches is filled with said substance, dividing surfaces (33,34) being generated at the junctions between the substance to be dosed and the auxiliary substance present in the lateral branches; in that the flow of the substance to be metered is interrupted both in the inlet branch, at a point situated before the first junction, and in the main branch at a point located after the second junction; and in that the auxiliary substance is finally circulated in the lateral connections so as to evacuate the part of substance contained in the main connection between the separation surfaces (35,36) at the two junctions.   7. Device for implementing the method according to claim 4 or 5, characterized in that it comprises a set of connected pipes comprising an inlet branch (1), of a defined metering volume which is delimited at one end by a connection junction (2) with one or more connections (3,4), and means (5) for introducing the substance to be dosed into the set of pipes in such a way that the substance flows 20 beyond said junction, and to evacuate - by circulation of an auxiliary substance, immiscible with the substance to be dosed, in the connections - the fraction (50) of substance which has advanced beyond from the junction, in a branch; and in that the inlet branch 25 comprises at least one valve (7) to prevent a reverse flow of the metered substance in the inlet branch during the evacuation of said fraction.   8. Device according to claim 7, characterized in that it comprises a pump (5) placed in one of the connections (3) of the pipe assembly in such a way that the pump both to suck the substance to be dosed in the pipe and to evacuate the fraction (15) of substance which has advanced beyond the junction, in the branch concerned. 35   9. Device for implementing the method 2623182 15 according to claim 6, characterized in that it comprises a set of connected pipes in which the input branch (20) divides, at the place of a junction (21), into a main branch (22) and a lateral branch (23) and in which the main branch (22,25) is further connected to another lateral branch ( 26) at the place of a second junction (24), means (27, 28) for introducing an auxiliary substance immiscible with the substance to be dosed at least in the lateral branches of the assembly; and means (27) for introducing the substance to be dosed at least into the input branch of the assembly and then into the main branch in such a way that at least the part of the main branch delimited by the two junctions is filled with said substance; and in that valves (29,32) are provided in the inlet branch before the first junction and in the main branch after the second junction to prevent the flow of the substance to be dosed in these branches so as to allow the evacuation of the dose of the substance, trapped between the two junctions, by the flow of an auxiliary substance passing through the lateral connections.   10. Device according to any one of claims 7 to 9, characterized in that the connections (1,3,4) of the pipes have a reduced diameter in the region of the junction (2).   11. Device according to any one of claims 7 to 10, characterized in that it constitutes part of an analysis apparatus used for chemical analyzes in the wet phase, in particular a clinical analyzer.