EP0271448A2 - Container for keeping liquid mediums - Google Patents

Abstract

This container (1) comprises a membrane (3) arranged in its wall (2) and whose centre has a thicker circular portion (4) in the inner face of which a groove (5) is arranged. The central portion (4) connected resiliently to the wall (2) by the membrane (3) is intended to come into contact with the end of an ultrasonic transducer. The groove (5) is used to generate a cavitation phenomenon in the liquid present in the container (1) with a view to mixing it. <IMAGE>

Description

The present invention relates to a test tube intended to contain a liquid medium in which a phenomenon of cavitation must be generated by transmission of ultrasound using an ultrasonic transducer brought into contact with the external face of the wall of this enclosure. .

It is known that in the case of chemical analyzes, in particular analyzes of biological liquids, the problem of homogenization is difficult to solve, in particular in an automated analysis process. However, the quality of the homogenization of the liquids to be analyzed is an important factor in the accuracy of the measurement.

There are different techniques for mixing liquids in the field of analysis, the most common being the agitation of the enclosure containing the substance to be mixed. This technique is essentially manual and does not lend itself to an automatic analysis process, in addition, its effectiveness is random, particularly at the molecular level. It has also been proposed a stirring technique by repeated suction and expulsion of the liquid to be homogenized, using a pipette. This mixing method is relatively effective, however it has two serious drawbacks, that of the risk of contamination of the different samples to be analyzed and the fact that it is impossible to guarantee that no drop of liquid remains attached to the pipette, thus distorting the dosage. The tendency of the modes of analysis being to work with very small volumes of samples, the importance of this sampling of drops on the precision is all the greater as the volume of sample is reduced.

It should also be noted that due to the very small volumes analyzed, the effectiveness of the mixing technique by agitation of the enclosure is further reduced due to the importance of the capillary forces which are exerted on the liquid placed in a enclosure of very small volume, generally tubular.

It has long been known that the transmission of ultrasound through a liquid causes cavitation phenomena. This property is used either for cleaning surfaces in contact with this liquid, or for the homogenization of the liquid combining several substances and / or containing solid suspensions, or even to form a mist.

It has already been proposed, in particular in FR-A-2,344,329 to transmit the ultrasound through the wall of a conduit, in order to homogenize a liquid. For this transmission to be effective, it is necessary to form a network of stationary vibrations on the wall of the duct which is thus gridded by bellies or active vibration zones. In the solution proposed in this document, one end of the conduit is fixed to a rigid base and the other end is free, the sonotrode secured to the same base as the tube being applied with significant pressure against the wall thereof. Such a solution is only effective provided that one end of the tube is rigidly connected to a frame and that the mass of the latter is significant. When these conditions cannot be met, this solution is inapplicable.

In US Pat. No. 3,633,877, a container is described intended to contain a liquid, a portion of the bottom of which is connected to the rest of the container by a rubber diaphgragm which makes this portion free to vibrate relative to the wall of the container. This portion is kinematically integral with an oscillator intended to communicate ultrasonic frequency vibrations to it. The face of this portion of the bottom in contact with the liquid in the form of a very flared cone, the top of which is directed towards the outside of the container.

DE 952.763 shows a pipe, a portion of the wall of which is made more elastic and is connected to an ultrasonic transducer, to communicate vibrations to the liquid contained in the pipe in order to homogenize it.

Both of these latter two solutions assume a rigid connection between the ultrasonic transducer and the wall to which the ultrasound is to be communicated, so that there is a rigid kinematic connection between this transducer and the driven wall. In the case of an analysis test tube, in particular for an automatic analysis device, such a kinematic connection is not possible, the ultrasound having to be communicated to the liquid by simple pressing of the transducer against the external face of the test piece.

The transmission of ultrasonic energy through the wall of a test tube with an energy density sufficient to cause cavitation in the liquid medium by simple pressing of the ultrasonic transducer poses various problems. The test piece must be made of a material which has a sufficiently low acoustic impedance to transmit the vibrations. The energy necessary to generate the cavitation must not be capable of damaging the test piece by breaking it or by melting it locally and superficially. When it comes to analyzes in the field of clinical chemistry, it is also important not to cause excessive heating of the liquid to be analyzed. In addition, the samples to be analyzed are generally of the order of a microliter, the test pieces are very small. In the case where the mixing of liquids must be carried out on an automatic analysis apparatus, it is obvious that the transducer used must be sufficiently small and therefore of low power. These different requirements are difficult to reconcile, since they are more or less contradictory.

The object of the present invention is to provide a solution which makes it possible to meet all of the required conditions.

To this end, the subject of this invention is a test tube intended to receive a liquid medium according to claim 1.

The proposed solution allows the adaptation of the ultrasonic mixing technique to test pieces using a low power transducer, without rigid connection either between the transducer and the test piece, or between the test piece and its support, which allows the use of this solution with an automatic analysis device in which the test pieces are removably fixed to a transfer member moving the test pieces opposite different stations corresponding to the different stages of analysis of the sample contained in the test tube. This solution also solves the problem of contamination of the samples, as well as that relating to the integrity of the volume of sample and of reagent placed in the test piece. Given the low energy required with the proposed solution to generate cavitation, there is no risk of damaging the test piece and excessively heating its contents.

• La fig. 1 est une vue en élévation de face de cette forme d'exécution.
• La fig. 2 est une vue en coupe agrandie selon la ligne II-II de la fig. 1.
• La fig. 3 est une vue en coupe selon la ligne III-III de la fig. 2.

The attached drawing illustrates, schematically and by way of example, an embodiment of the enclosure which is the subject of the present invention.

• Fig. 1 is a front elevation view of this embodiment.
• Fig. 2 is an enlarged sectional view along line II-II of FIG. 1.
• Fig. 3 is a sectional view along line III-III of FIG. 2.

At first, it was thought that it was enough to provide on the wall of the enclosure an elastic zone similar to a membrane and to apply the end of an ultrasonic transducer against this elastic zone. Tests carried out under these conditions with a liquid medium in which a solid phase must be uniformly distributed, have shown that the mixing effect, linked to cavitation, was not constant. It appeared that the ulstrasons transmitted through the elastic membrane did not always cause cavitation and that this was not related to the elasticity of the membrane. It was then that it was found that the only walls which made it possible to generate cavitation were those which exhibited cracks induced following the application of the ultrasonic transducer, and which were produced in materials which are capable of transmitting ultrasound with a good yield, these materials having in particular a coefficient of elasticity greater than 25 · 10⁴ N / cm². In the case of plastics, there may be mentioned, by way of example, polystyrene and polyacrylic.

Given that under the effect of the pressure exerted on the wall of the test piece by the transducer, the edges of the crack move apart towards the internal face of the wall, we had the idea to try to reproduce the same effect without cracking but with small grooves made on the internal face. These tests made it possible to demonstrate that the presence of grooves, or even simple re-entrant cones formed in the thickness of the wall by hot tips, made it possible to obtain a cavitation effect. It seems that it is possible to interpret this phonomene, as resulting from a variation of the volume inside the groove likely to create in the portion of the liquid contained in this groove a local pressure lower than the vapor pressure of this liquid.

Among the comparative tests carried out with and without groove and with the same ultrasonic transducer supplied with the same current, it was found that the presence of the groove immediately makes it possible to generate cavitation, while the absence of groove gives no results and may even, by prolonging the time of application of the sonotrode against the wall of the test piece, cause its deformation, following heating. This experience shows that with a higher power ultrasonic transducer, there was a risk of damaging the test piece before creating cavitation in the liquid it contains. It is obvious that to generate cavitation, the groove made in the internal face of the wall of the test piece must be sufficiently closed. As a general rule, the width of the side of the groove open towards the inside of the test piece and therefore causing the portion of liquid contained in this groove to communicate with the rest of the liquid contained in the test piece must not be greater at the depth of this groove. If this groove is triangular, or conical, the angle must not exceed 60 °.

The embodiment of Figs 1 to 3 consists of a tubular element 1 of rectangular section and widening slightly upwards, intended to receive a sample to be analyzed with its appropriate reagent (s).

The side wall 2 has a portion 3 of square shape with rounded angles in which the wall is thinned in order to give it a certain elasticity. This thinned portion 3 surrounds a circular portion 4 similarly thickness than that of the wall surrounding the thinned portion 3. The walls of this tubular element 1 are relatively rigid, they are made of polystyrene or polyacrylic injected 0.8 mm thick, while the thinned portion 3 has a thickness 0.3 mm and a minimum width of 2 mm, the circular portion 4 has 2 mm in diameter. These dimensions are not critical and can be changed in fairly large proportions. Similarly, the thinned portion 3 could have an annular shape. It essentially serves to ensure good contact between the circular portion 4 and the ultrasonic transducer intended to press against it. This intimate contact between the face of this circular portion 4 and the sonotrode is indeed an essential condition for the transmission of ultrasonic waves.

On the internal face of the wall of this tubular enclosure 1 at the center of the circular portion 4, a groove 5 is formed. As already explained, the role of this groove is decisive for inducing cavitation in the liquid medium, and is all the more decisive since it has made it possible to demonstrate that it was possible to induce cavitation without the thinned portion 3, provided that there is good contact between the sonotrode and the external face of the tubular element 1, opposite the groove 5. This therefore proves the predominant role of this groove 5 over that of the elastic portion 3 , which only seems to have the role of ensuring good contact with the sonotrode by allowing the external face of the portion 4 a certain angular displacement if the end of this sonotrode is not perfectly parallel to its external face.

Claims (4)

1. Test tube intended to receive a liquid medium, at least a portion of its wall being shaped to transmit to said liquid medium ultrasonic waves of energy intensity capable of causing cavitation therein, characterized in that the wall of the test piece is made in one piece using a material whose elastic modulus is above 25 · 10⁴ N / cm² the internal face of the wall of this test piece comprising, in the vibration transmission zone ultrasonic, a groove formed in the thickness of this wall and whose width of the opening in this internal face is not greater than its depth, to create in this groove volume variations capable of generating in the liquid contained in this groove a local pressure lower than the vapor pressure of the liquid. 2. A test piece according to claim 1, characterized in that the wall portion containing said groove is surrounded by an area of reduced thickness, capable of flexing elastically relative to this wall, when the end of an ultrasonic transducer is applied against it. 3. A test piece according to claim 2, characterized in that said wall having said defined zone of reduced rigidity is planar. 4. A test piece according to claim 2, characterized in that said demarcated area of reduced rigidity comprises an elastic part of annular shape connecting a more rigid central part to the rest of the wall of this enclosure.

Images