FR3034525A1 - DEVICE FOR TRANSFERRING LIQUID SAMPLES - Google Patents

Abstract

The transfer device (10) comprises a sampling needle (24), means (26) for moving the needle (24) between the sample holder (12) and the analyzing device (14), a selector (28) comprising at least first (28A), second (28B) and third (28C) channels, whose central channel (28A) is connected to the sampling needle (24), the selector (28) being clean selectively connecting two channels to each other, a sampling syringe (30), connected to the second channel (28B) of the selector (28), and a conveying syringe (32), connected to the third channel (28C) of the selector (28), intended to contain an incompressible liquid.

Description

The present invention relates to a device for transferring liquid samples from a sample carrier to an analysis device.

The analysis device is for example a spectrophotometer, intended to measure the absorption, diffusion or fluorescence of liquid samples. For this purpose, the analysis device comprises a measuring cell for liquid sample, through which such a sample can transit. It is already known, in the state of the art, transfer devices developed and optimized to perform high-speed measurements on such an analysis device. Such a transfer device is permanently assembled with the analysis device which is generally dedicated to only one type of experiment, so that it is difficult to transport from one analysis device to another. This transfer device can be particularly bulky, having significant dimensions related to the function for which it has been optimized, namely the rapid injection of samples into the measuring cell. In addition, the known transfer devices are not suitable for injecting non-homogeneous samples, having unconventional physicochemical properties, especially very concentrated, viscous, semi-precipitated or semi-crystalline solutions, etc. Indeed, such a device is generally optimized for a standard type of sample homogeneous and low viscosity. The object of the invention is in particular to remedy these drawbacks, by proposing a compact sample transfer device capable of conveying to any analysis device all types of liquid samples, in particular samples having physicochemical properties. unconventional. For this purpose, the subject of the invention is in particular a device for transferring liquid samples from a sample carrier to an analysis device, the transfer device comprising a sampling needle, characterized in that it comprises: means for moving the sampling needle between the sample holder and the analysis device; a selector comprising at least first, second and third channels, the central channel of which is connected to the sampling needle; the selector being adapted to selectively connect the central channel with one of the other channels, - a sampling syringe, connected to the second channel of the selector, 3034525 2 - a routing syringe, connected to the third channel of the selector, intended to contain an incompressible liquid. Such a transfer device is able to take all types of samples by means of the sampling needle, when this needle is connected to the sampling syringe, and then to convey this sample precisely to the analysis device, when the needle is connected to the syringe for routing, pushing the sample with said incompressible liquid. Advantageously, an air bubble is provided between the sample and the incompressible liquid, in order to avoid dilution of the sample.

A transfer device according to the invention may further comprise one or more of the following features, taken alone or in any technically feasible combination. - The selector comprises a fourth channel, connected to a source of incompressible liquid, including water. 15 - The selector comprises a fifth channel, connected to a source of compressed air. The transfer device comprises a programmable microcontroller capable of controlling the displacement means, the selector, the sampling syringe and the routing syringe according to a predefined sequence. 20 - The transfer device comprises remote control means, allowing an operator to remotely control the moving means, the selector, the sampling syringe and the routing syringe. - The selector is formed by a multi-channel valve. The invention also relates to a method for transferring liquid samples from a sample holder comprising at least one sample receptacle to an analysis device, by means of a transfer device as defined above, characterized in that it comprises: - a step of positioning the sampling needle in a sample receptacle of the sample holder, - a step of connection, by the selector, of the central channel, connected to the sampling needle, with the second channel, connected to the sampling syringe, - a step of sampling the sample in the sampling needle, by activation of the sampling syringe, - a step of moving the needle of withdrawing from the receptacle, 3034525 3 - a step of moving the sample in the sampling needle, by activating the sampling syringe to introduce a bubble of air following the sample, a step of moving the sampling needle to an injection element of the analysis device, a step of injecting the sample contained in the sample. sampling needle in the injection element, by activation of the sampling syringe, - a step of connecting the central channel, connected to the sampling needle, with the third channel, connected to the transport syringe and a step of conveying the sample to a measuring cell of the analysis device, by activating the delivery syringe so as to inject an incompressible liquid following the air bubble. . Advantageously, the method according to the invention may further comprise one or more of the following characteristics, taken alone or in any technically feasible combination. - The transfer process comprises a subsequent step filling the transport syringe with incompressible liquid. The transfer process comprises a rinsing step, during which the central channel, connected to the sampling needle, is connected to the fourth channel, connected to the source of liquid, the liquid thus circulating in the needle. sampling then in the analysis device. - The transfer process comprises a drying step, during which the central channel, connected to the sampling needle, is connected to the fifth channel, connected to the source of compressed air, the air thus flowing in the sampling needle 25 and then in the analysis device. The invention will be better understood on reading the description which follows, given solely by way of example and with reference to the single appended figure, schematically showing a transfer device according to an exemplary embodiment of the invention. invention.

FIG. 10 shows a device 10 for transferring liquid samples, from a sample holder 12 to an analysis device 14. Said sample holder 12 comprises a body 15 in which receptacles 16 are formed, in which samples are arranged for analysis. These receptacles 16 are for example formed by housings in which are inserted vials, in particular glass, including the samples. The receptacles 16 are for example arranged in rows, each row extending in a longitudinal direction X, and the rows being aligned in a transverse direction Y perpendicular to the longitudinal direction X. Advantageously, the sample holder 12 comprises temperature control means. For this purpose, the body 15 of the sample holder 12 comprises means 5 for circulating a coolant, in particular a refrigerant fluid, arranged to perform a heat exchange with the receptacles 16. These regulating means make it possible to maintain a sample contained in the sample holder 12 at a predefined temperature. This is especially necessary when the sample needs to be kept at this preset temperature.

The analysis device 14 is for example a spectrometer, comprising a measuring cell 18, through which at least one sample is intended to circulate. The analysis device 14 further comprises means for spectrometric analysis of the sample passing through the measuring cell 18. Such a device is for example intended to measure absorption, diffusion or fluorescence, etc. of the sample. For this purpose, the spectrometric analysis means are capable of passing a beam through the measuring cell 18, for example a beam of X-ray, visible light, ultraviolet or infrared. An injection element 20 is arranged upstream of the measuring cell 18. This injection element 20 comprises an injection opening through which the samples are intended to be injected, and it is connected to the measuring cell 18 of the analysis device 14 by at least one pipe 21. Advantageously, the analysis device 14 also comprises temperature control means. Thus, the temperature of a sample is regulated during its analysis. This is especially necessary when the sample has to be analyzed at a predefined temperature. Advantageously, a collection device 22 is arranged downstream of the analysis device 14, in order to collect the samples that have passed through the measurement cell 18. The collection device 22 is connected to the measurement cell 18 by at least one line 23. The collection device 22 comprises, for example, a dispensing needle, means for displacing this dispensing needle from an outlet of the analysis device 14 for conveying a sample collected by the dispensing needle to the dispensing needle. to a sample carrier, which may be the sample carrier 12 described above, or another sample carrier. The transfer device 10 comprises a sampling needle 24.

The transfer device 10 further comprises means 26 for moving the sampling needle 24 between the sample holder 12 and the analysis device 14. The displacement means 26 are particularly suitable for moving the needle. 5 of the sample 24 along the longitudinal axis X and / or the transverse axis Y to move it from one of the receptacles 16, from which a sample has been taken, to the injection element 20 in which the sample will be injected. Advantageously, the displacement means 26 are also adapted to move the sampling needle 24 along a vertical axis Z perpendicular to the longitudinal X and transverse axes Y, to allow the insertion and withdrawal of the needle. sampling 24 in a receptacle 16 and in the opening of the injection element 20. In the example described, the sample holder 12 also comprises displacement means along the transverse direction Y, perpendicular to the direction longitudinal direction X and in the vertical direction Z. The displacement of the sample support 12 in the transverse direction Y makes it possible to bring a desired row of receptacles 16 within reach of the sampling needle 24. The sampling needle 24 can then move in the longitudinal direction X next to a desired receptacle 16 of said row and then inserted into this receptacle 16 being moved in the vertical direction Z.

The transfer device 10 further comprises a selector 28, comprising at least one central channel 28A, a second channel 28B and a third channel 280, and adapted to selectively connect the common channel 28A with one of the other channels. The selector 28 according to the invention further comprises a fourth channel 28D and a fifth channel 28E, and could include other additional channels if necessary.

The selector 28 is for example formed by a multi-channel valve. Said sampling needle 24 is connected to the central channel 28A of the selector 28. Furthermore, the transfer device 10 comprises a sampling syringe 30, connected to the second channel 28B of the selector 28. This sampling syringe 30 comprises a body 30A and a piston 30B housed in the body 30A and defining therewith a sampling chamber. The sample chamber is filled with air, and the piston 30B is movable in the body 30A to vary the volume of the sample chamber, thereby generating a vacuum or an overpressure. Thus, when the central lane 28A is connected to the second lane 28B, the sampling syringe 30 allows a sample to be taken from the sampling needle 24, generating a vacuum.

The transfer device 10 further comprises a routing syringe 32, connected to the third channel 280 of the selector 28. This routing syringe 32 comprises a body 32A and a piston 32B housed in the body 32A and delimiting with the a room of routing. The delivery chamber is intended to be filled with an incompressible liquid, for example water. The piston 32B is movable in the body 32A to vary the volume of the conveying chamber, thereby generating an overpressure. Thus, when the central channel 28A is connected to the third channel 28C, the conveying syringe makes it possible to push a sample by generating an overpressure, the sample thus being pushed by the incompressible liquid. The sampling syringes 30 and routing 32 are provided with an L valve which allows their purge or their supply air or water respectively. A source of rinsing liquid 34, especially water, is connected to the fourth channel 28D. This liquid source 34 makes it possible to rinse the analysis device 14 when the sampling needle 24 is connected to the injection element 20 and the central channel 28A is connected to the fourth channel 28D. In addition, a source of compressed air 36 is connected to the fifth channel 28E. This source of compressed air 36 makes it possible to dry the analysis device 14 when the sampling needle 24 is connected to the injection element 20, and the central channel 28A is connected to the fifth channel 28E . Advantageously, the transfer device 10 comprises a programmable microcontroller capable of controlling the displacement means 26, the selector 28, the sampling syringe 30, the routing syringe 32, and the sources of liquid 34 and compressed air 36 in a predetermined sequence. The transfer device 10 can thus be remotely controlled by an operator who can sequentially control the moving means 26, the selector 28, the picking and conveying syringes 32, and the liquid and air sources 34 A method of transferring liquid samples from the sample holder 12 to the analyzer 14 by means of the transfer device 10 described above will be described below. The transfer method first comprises a step of positioning the sampling needle 24 in a sample receptacle 16 of the sample holder 12. For this purpose, as described above, the sample holder 12 is, if necessary, moved in the transverse direction Y to bring a desired sample row within reach of the picking needle 24, then the picking needle 24 is moved in the longitudinal direction X to bring it next to the 3034525 7 receptacle 16 of the sample to be taken. The sampling needle 24 is finally moved in the vertical direction Z to be immersed in the receptacle 16. The method then comprises a step of connecting, in the selector 28, the central channel 28A, connected to the needle 24, with the second channel 28B, connected to the sampling syringe 30. The method then comprises a sample taking step, initially contained in the corresponding sample receptacle 16, in the sampling needle 24, by activation of the sampling syringe 30, the piston 30B of which moves to generate a depression, thereby sucking the sample into the sampling needle 24. The sampling needle 24 is withdrawn from the sample receptacle 16 by a displacement along the axis vertical Z, then the activation of the sampling syringe 30, the piston 30B moves to generate a depression in order to move the sample in the preloading needle 24 tively.

There is also provided a step of moving the sample in the sampling needle 24, by activating the sampling syringe 30 to determine a volume of air, in particular an air ball of constant volume, which will serve to separate the sample of the incompressible liquid during the routing in the analysis device 14.

It should be noted that these positioning and sampling steps can be repeated as necessary, in particular to take more than one sample simultaneously in the same needle 24, in the case where it is desired to analyze a mixture or a dilution of several samples. Once the sample, or sample mix, to be analyzed is taken from the needle 24, the method includes a step of moving the picking needle 24 to the injection member 20 of the needle 24. analysis device 14. During this displacement step, the sampling needle 24, previously extracted from the receptacle 16 by a displacement along the vertical axis Z as indicated above, is displaced along the longitudinal axis X and / or transverse Y until it is opposite the injection inlet of the injection element 20, and is then displaced in the vertical direction Z until it is inserted into this injection inlet. The method then comprises a step of connecting the central channel 28A, connected to the needle 24, with the third channel 280, connected to the routing syringe 32. At this stage, the delivery chamber is filled with incompressible liquid, especially water.

The method then comprises a step of conveying the sample to the measuring cell 18, by activation of the routing syringe 32 so as to inject the incompressible liquid following the air bubble, and thus perform the thrust of the sample through this incompressible liquid. The sample is thus transported in a simple, efficient and precise manner, regardless of its properties, in particular for a non-homogeneous and viscous sample. In the figure, there is shown in the measuring cell 18, the sample designated by the reference 38, air flanking the sample, designated by the reference 40, and the incompressible liquid pushing the sample, designated by reference 42.

Due to the air bubble 40, the sample 38 is not in contact with the liquid 42, and is therefore not diluted therein. During its passage in the measuring cell 18, the sample 38 is analyzed in a conventional manner by the spectrometric analysis means. Once the sample has been analyzed, it is conveyed, again by means of the routing syringe 32, to an output of the analysis device, to which it is collected by the collection device 22. this sample transfer, the transfer device 10 is reset. For this purpose, the piston 30B of the sampling syringe 30 is positioned in an initial position, in which the sampling chamber is emptied. In addition, a step is performed for filling the delivery syringe 32 with incompressible liquid. Advantageously, the transfer method also comprises a step of rinsing the analysis device 14. During this step, the central channel 28A, connected to the sampling needle 24, is connected to the fourth channel 28D, connected to the liquid source, in order to circulate liquid in the sampling needle 24 and in the analysis device 14. This rinsing step is followed by a drying step, during which the central channel 28A connected to the sampling needle 24 is connected to the fifth channel 28E, connected to the source of compressed air, in order to circulate the compressed air in the sampling needle 24 and in the analysis device 14 to perform the drying of 30 this one. Thus, at the end of this drying step, the analysis device 14 comprises only air, and its walls are dry, eliminating the risk of dilution, with residual liquid, of a sample subsequently analyzed. Note that the invention is not limited to the embodiment described, but could have various variants. 35

Claims (10)

REVENDICATIONS1. Device (10) for transferring liquid samples from a sample holder (12) to an analyzing device (14), the transfer device (10) having a sampling needle (24), characterized in that it comprises: - means (26) for moving the sampling needle (24) between the sample holder (12) and the analysis device (14), - a selector (28) comprising at least first (28A), second (28B) and third (28C) lanes, the center lane (28A) of which is connected to the sampling needle (24), the selector (28) being adapted to selectively connect the central lane (28A) with one of the other channels (28B, 28C, 28D, 28E), - a sampling syringe (30), connected to the second channel (28B) of the selector (28), - a conveying syringe (32), connected to the third channel (28C) of the selector (28), intended to contain an incompressible liquid. 2. Transfer device (10) according to claim 1, wherein the selector (28) comprises a fourth channel (28D), connected to a source of incompressible liquid (34), including water. The transfer device (10) according to claim 1 or 2, wherein the selector (28) has a fifth channel (28E) connected to a source of compressed air (36). 4. Transfer device (10) according to any one of the preceding claims, comprising a programmable microcontroller, adapted to control the displacement means (26), the selector (28), the sampling syringe (30) and the syringe d routing (32) according to a predefined sequence. 5. Transfer device (10) according to any one of the preceding claims, comprising remote control means, allowing an operator to remotely control the displacement means (26), the selector (28), the syringe of sampling (30) and the conveying syringe (32). The transfer device (10) according to any one of the preceding claims, wherein the selector (28) is formed by a multi-channel valve. 3034525 10 A method of transferring liquid samples from a sample holder (12) having at least one sample receptacle (16) to an analyzer (14) by means of a transfer device (10). ) according to any one of the preceding claims, characterized in that it comprises: - a step of positioning the sampling needle (24) in a sample receptacle (16) of the sample holder (12) - a step of connection, by the selector (28), of the central channel (28A), connected to the sampling needle (24), with the second channel (28B), connected to the sampling syringe (32) A sample collection step in the sampling needle (24), by activation of the sampling syringe (30), a step of moving the sampling needle (24) out of the sampling needle (24); receptacle (16), - a step of moving the sample in the sampling needle (24), 15 by activating the sampling syringe (30) to introduce an air bubble (40) following the sample (38); - a step of moving the picking needle (24) to a sample element (38); injection (20) of the analysis device (14), - a step of injecting the sample (38) contained in the sampling needle (24) into the injection element (20), by activation of the sampling syringe (30), - a step of connecting the central channel (28A), connected to the sampling needle (24), with the third channel (280), connected to the transport syringe ( 32), and - a step of conveying the sample (38) to a measuring cell (18) of the analysis device (14), by activation of the conveying syringe (32) so as to injecting an incompressible liquid (42) following the air bubble (40). A transfer method according to claim 7, by means of a transfer device (10) according to claim 2, comprising a subsequent step of filling the conveying syringe (32) with incompressible liquid. The transfer method according to claim 7 or 8, by means of a transfer device (10) according to claim 2, comprising a rinsing step, during which the central channel (28A), connected to the needle. sample (24), is connected to the fourth channel (28D), connected to the liquid source (34), the liquid thus flowing in the sampling needle (24) and then in the analysis device (14) . 3034525 11 Transfer method according to one of claims 7 to 9, by means of a transfer device (10) according to claim 3, comprising a drying step, during which the central channel (28A), connected 5 (24), is connected to the fifth channel (28E), connected to the source of compressed air (36), the air thus flowing in the sampling needle (24) and then in the analyzing device (14).