FR2964460A1 - STORAGE BOX FOR AFM PROBES - Google Patents

Abstract

The invention relates to a storage box for AFM probes (1) comprising a tip (2) disposed on a lever (3) integral with a support (3 '), said box comprising a base (4) comprising a bottom (5). ) and a side wall (6) defining a storage space (7), said bottom (5) comprising at least one housing (8) adapted to receive the tip (2) of a probe (1). The box comprises a lid (9) able to close and release said storage space (7), and holding means able to block the probes (1) in the storage space (7) when the tips of the probes ( 1) are positioned in their respective housings (8). According to the invention, the box comprises sealing means (15) for sealing the liquid storage space (7) when said storage space (7) is closed by the lid (9) and filled of a liquid.

Description

The invention relates to the field of conditioning, transport, surface treatment (chemical or physical) and cleaning probes for atomic force microscopy systems. The invention more particularly relates to a storage box for 5 AFM probes (Atomic Force Microscopy). The AFM probes comprise a tip disposed on a lever (or "cantilever"), itself fixed on a support. These probes are fragile and expensive. When not in use, the AFM probes are stored in transport boxes or cassettes for packaging and transporting the AFM probes without the risk of damaging them. There are known plastic transport boxes having at their bottom a layer of adhesive polymer in gel form. This adhesive polymer layer is intended to hold the AFM probes. The disadvantage of these boxes is that since the probes are in contact with the gel, it is often necessary to treat the surface of the tips to clean them after their conditioning. In addition, the presence of gel makes it impossible to physically or chemically treat the probes in the box. As for the cassettes, they are intended to be loaded into atomic force microscopes in order to supply the latter with AFM probes. Document WO 2008/002922 discloses a cassette made partly of metal which comprises a base having a plurality of housings for AFM probes, and a cover intended to cover the probes. The lid includes a series of parallel blades which function to exert pressure on the probes to lock them in their housing when the lid is closed. The parallel blades are made of conductive material, and preferably of PTFE (polytetrafluoroethylene) carbon. Nevertheless, these cassettes of the prior art are only intended for the loading of probes in an atomic force microscope, and do not allow the transport of the probes in a liquid medium, nor the chemical treatment in liquid medium of these probes. There is therefore a need in the state of the art for a storage box for AFM probes for transporting them in a liquid medium, and the application of chemical treatments in liquid medium on these probes, without the risk of damaging them. Such a storage box is provided according to the invention. The applicant has focused on the development of a storage box 5 for AFM probes comprising a tip disposed on a lever secured to a support. The box comprises: - a base having a bottom and a side wall defining a storage space, said bottom comprising at least one housing adapted to receive the tip of a probe, 10 - a cover adapted to close and to clear said space of storage, - holding means able to block the probes in the storage space when the tips of the probes are positioned in their respective housing. According to the invention, the storage box for AFM probes comprises sealing means for sealing the liquid storage space when said storage space is closed by the lid and filled with a liquid. Thus, the invention provides a storage box for AFM probes 20 for transporting the probes in a liquid medium, and the application of chemical treatments in a liquid medium on these probes. It is also possible to store and transport the probes over long distances without risk of damaging them. The tightness of the storage box also makes it possible to avoid the contamination of the probes by external pollutants (air, for example). The use of a liquid makes it possible to avoid the formation of electrostatic charges. In various possible embodiments, the present invention also relates to the following features which may be considered individually or in all their technically possible combinations and each bring specific advantages: the holding means are movable relative to the cover; Thus, the probes can be held fixed when the lid is open, it is possible to apply simultaneously on several probe tips the same physical treatment (plasma, UV / ozone, metal deposits) or the same chemical treatment in a liquid medium ( oxidation, grafting, ...). It is possible to clean all probes at once with reactive solutions to remove contaminants. the base, the cover and the holding means consist of a material which does not present any risk of contamination of the tip of the AFM probe, and which is inert with respect to the treatment and cleaning liquids of the probes; the materials suitable for the base, the lid and the holding means are chosen from polytetrafluoroethylene (PTFE) and polytetrafluoroethylenes loaded with inert materials; the inert materials are chosen from glass, bronze, bronze / graphite, ceramics, ekonol, calcium fluoride, stainless steel, molybdenum disulfide (MoS2), glass / MoS2. Thus, the invention makes it possible to prevent the pollutants from contaminating the probes from the materials constituting the storage box, when a liquid solution is used. These pollutants may be carbon, for example, when the storage boxes of the prior art are made of carbon-based PTFE. The carbon mixes with the liquid and then contaminates the probes. Pollutants can be due to metal when the prior art storage box includes metal parts. The pollutants may be due to the polymer gel residues when gel is used in the prior art storage boxes. These residues are in solid or gaseous form and come from the depolymerization of the gel. Pollutants can also be due to any unwanted dust or deposits. The storage box is inert with respect to the probes and the liquids, and can be drastically washed with a reactive solution (for example a mixture of H2SO4 / H2O2, a mixture of HCl / HNO3, surfactant solutions based on alkylbenzenesulphonates) in order to guarantee absence of contaminants, which is not possible with the prior art storage boxes comprising polymer-based metal or gel. the holding means comprise a support element cooperating with locking means so that said support element is able to exert pressure on all the probes to keep them locked against the bottom of the base; bearing member having a flat bearing surface, and the dimension of the bearing member being adapted so that the latter can cover all of the housing of the base; the support element having an upper surface, the support element is provided with a protrusion projecting from the said upper surface, the cover being adapted, when closed, to exert pressure on the said element; support via said protrusion, to block the probes against the bottom of the base; the locking means comprise a screw cooperating with a threaded hole formed in the center of the base, the support element having an orifice at its center, the screw being able to pass through the orifice of the support element and to screw into the threaded hole of the base to block the probes between the support member and the base; the base comprises an outer body, and an inner body movable relative to the outer body, said inner body comprising said bottom and said lateral wall delimiting the storage space of the base, and being able to be housed in said outer body to form the base; Thus, the inner body containing probes can be removed while the outer body still comprises liquid. the locking means comprise a threaded rod secured to the lower part of the support element, said threaded rod being able to be screwed into a threaded hole formed in the center of the inner body of the base, the support element comprising a stop protruding from its upper surface, the cover being adapted, when closed and when the threaded rod is screwed into the threaded hole of the inner body, to exert pressure on said stop to lock the inner body against the outer body ; - The means for sealing the storage space comprises a seal disposed between the base and the lid; - The storage box comprises a filling and draining orifice of the liquid, and a closing means adapted to close said filling and emptying orifice. The invention will be described in more detail with reference to the accompanying drawings in which: FIG. 1 shows a known AFM probe; FIG. 2 represents a storage box for AFM probes in exploded view, according to a first possible embodiment of the invention; FIG. 3 represents an exemplary support element; FIG. 4 represents the base of the storage box for AFM probes, viewed from above; FIG. 5 represents the base of the storage box for AFM probes, seen from the side; FIG. 6 represents a storage box for dismounted AFM probes, according to a second possible embodiment of the invention; - Figure 7 shows a storage box for AFM probes in exploded view, according to a third possible embodiment of the invention. FIG. 1 represents a known AFM probe 1 comprising a tip 2 disposed on a lever 3, itself secured to a support 3 '. The AFM probe 1 comprises a lower face 19 on which the tip 2 is disposed, and an upper surface 20 without a tip. FIG. 2 represents a storage box for AFM probes 1, according to a first possible embodiment of the invention. The storage box comprises a base 4 having a bottom 5 and a side wall 6 defining a storage space 7. The bottom 5 comprises a housing 8 adapted to receive the tip 2 of one or more probes 1 to store them in the box storage. In the example of Figure 2, the base 4 comprises a single housing 8 formed of a circular groove dug in the bottom 5 of the base 4. The groove is centered relative to the center of the base 4 and along the side wall 6 of the base 4. Its depth and width are adapted to the dimensions of the tip 2 of the probes. The base 4 comprises recesses 43 distributed circumferentially around the center of the base 4, and opening into the housing 8. The recesses 43 are located between the center of the base 4 and the groove. They have an elongated shape and extend in portions of radius passing through the center of the base. They have dimensions adapted to receive the rest of the probe formed of the lever 3 and the support 3 '. The lower face 19 of each probe rests in one of the recesses 43.

In the example of Figures 2 to 5, the base comprises eight recesses 43. The storage box comprises holding means adapted to block the probes 1 in the storage space 7 when the tips 2 of the probes 1 are inserted in their 8 respective dwellings. The storage box includes a cover 9 capable of closing and releasing the storage space 7. In the examples of FIGS. 2 to 7, the storage box has a circular section. Other sections are also possible such as elliptical sections, for example. The storage box includes sealing means 15 for sealing the liquid storage space 7 when the storage space 7 is closed by the cover 9 and filled with a liquid. These liquids may be reactive solutions for performing a chemical treatment on the probes 1. The means for sealing the storage space 7 comprise a seal 15 disposed between the base 4 and the cover 9. The method embodiment of Figures 2 to 5 is described in detail below. The seal 15 is an O-ring which is housed in a circular groove 21 formed in the side wall 6 of the base 4, on its upper part. When the cover 9 is closed, the latter compresses the seal against the base 4, sealing the liquid storage box. The cover 9 can be locked by screwing on the base 4. Alternatively, the cover 9 can be locked on the base 4 by means of threaded rods screwed into threaded holes 23 provided in the side wall 6 of the base 4. The rods Threads are able to pass through orifices 22 formed on the cover 9 before reaching the base 4. Preferably, the threaded rods are three in number. When the threaded rods are inserted into the orifices 22 of the lid 9, butterfly nuts, for example, are attached to the threaded rods to lock the lid 9 against the probes.

The holding means are movable relative to the cover 9 between a locking position of the probes, and a release position of the probes. The holding means can block the probes 1 by compressing them against the bottom 5 of the base 4.

The holding means are dissociated from the cover 9 and are independent of the latter. The holding means can hold the probes 1 when the cover 9 is removed. The holding means comprise a bearing element 10 cooperating with locking means. The locking means exert a pressure on the support element 10, which transmits it to all the probes 1 to keep them locked against the bottom 5. More specifically, the support element 10 comprises a lower face 30 ' which exerts a pressure on the upper face 20 of the probes 1, as shown in FIG. 3. The bearing element 10 may comprise a ring-shaped protuberance 10 'projecting from the lower face 30' of the Support element 10. The protrusion 10 'is positioned at the periphery of the support element 10, and is intended to be in contact with the support 3' of the probe 1. The locking means comprise a cooperating screw 11 with a threaded hole 13 provided in the center of the base 4. The support element 10 comprises an orifice 14 at its center. The screw 11 is able to pass through the orifice 14 of the support element 10, and to screw into the threaded hole 13 of the base 4 to block the probes 1 between the support element 10 and the base 4 The screw 11 comprises a threaded portion 31 and a head 32 which can be flat. The support member 10 comprises an upper face 30 on which the head 32 of the screw 11 abuts to exert a pressure. Alternatively, the threaded hole 13 of the base 4 and the orifice 14 of the support element 10 may not be centered relative to the storage box. The bearing element 10 has a flat bearing surface. The dimension of the support element 10 is adapted so that the latter can cover all the housings 8 of the base 4. The diameter of the support element 10 is smaller and close to the diameter of the storage space 7 from the base 4.

The base 4, the cover 9 and the holding means consist of a material which does not present a risk of contamination of the tip of the AFM probe, and which is inert with respect to the treatment and cleaning liquids. of the probe. The liquid contained in the AFM box is only in contact with the aforementioned material. The materials suitable for the base 4, the cover 9 and the holding means are chosen from polytetrafluoroethylene (PTFE), polytetrafluoroethylenes loaded with inert materials, and glass. The inert materials are selected from glass, bronze, ceramic, ekonol, calcium fluoride, stainless steel, molybdenum disulfide (MoS2), glass / MoS2 (commercial reference: "isoflon"). The glass may be a pigmented glass, for example. For example, polytetrafluoroethylene may be charged with 5%, 15%, 25%, or 40% glass by weight.

The glass may be an aluminosilicate glass ("Goodfellow"), a borosilicate glass ("Vio-glasses"), silica or vycor ("Goodfellow"). The material suitable for the base 4, the cover 9 and the holding means may also be a copolymer of ethylene-tetrafluoroethylene (ETFE) ("goodfellow"), or a copolymer of ethylene-chlorotrifluoroethylene (E-CTFE) (" Goodfellow "). According to another variant, the base 4, the cover 9 and the holding means may consist of a first material such as metal, plastic or a ceramic, for example, and completely covered by a layer of a second material such as PTFE or PTFE reinforced with the aforementioned inert material. Preferably, the base 4, the cover 9 and the holding means are composed of pure PTFE, that is to say that they are without additive or charge. This prevents contamination of the liquid and probes by pollutants from the storage box.

In the following embodiments, the base 4, the cover 9 and the holding means have the aforementioned characteristics. The storage box comprises a filling and emptying orifice 16 of the liquid, and a closing means 12 able to close the filling and emptying orifice 16.

The closure means 12 is a PTFE stopper. The liquid can be injected into the storage space 7, and drained from the latter through the filling and emptying orifice 16, by means of a syringe for example.

Figure 4 shows the base 4 of the storage box for AFM probes, seen from above. Figure 5 shows the base of the storage box for AFM probes, viewed from the side. Dimensions are given as an example. The base 4 may have a diameter of 66 mm and a height of 33 mm. The recesses 43 may have a width of 2 mm. The storage space 7 may have a diameter of 41 mm. The slot 8 in the form of a groove may have a width of 3 mm. The inner diameter of the groove can be 35 mm and its outer diameter 41 mm. The depth of the groove can be 0.2 mm.

FIG. 6 represents a storage box for AFM probes 1, according to a second possible embodiment of the invention. The storage box is cylinder shaped but other shapes are also possible, such as an ovoid shape, for example. The storage box comprises a base 4 comprising a bottom 5 and a side wall 6 defining a storage space 7. In the example of FIG. 6, the base 4 comprises a single housing 8 formed by a circular groove dug in the bottom 5 of the base 4. The groove is centered with respect to the center of the base 4 and runs along the side wall 6 of the base 4. Its depth and its width are adapted to the dimensions of the tip 2 of the probes. The base 4 comprises recesses 43 distributed circumferentially around the center of the base 4, and opening into the housing 8. The recesses 43 are located between the center of the base 4 and the groove. They have an elongated shape and extend in portions of radius 30 passing through the center of the base. They have dimensions adapted to receive the rest of the probe formed of the lever 3 and the support 3 '. The lower face 19 of each probe rests in one of the recesses 43. According to another possible embodiment, the bottom 5 may comprise several housings 8 adapted to receive the tip 2 of a probe 1 to store the probe 1 in the box. storage.

According to this embodiment, the housings 8 are recesses or recesses of circular section formed in the bottom of the base. Other shapes are also possible for the cavities. The size (diameter) of the housings 8 is greater than the dimension of the tip 2 of the probe 1, and close to it. The depth of the housing 8 is such that almost the entire tip 2 can be inserted into it. The distribution of dwellings 8 is varied. The housings 8 may be equidistant from each other or may be distributed circumferentially around the center of the base 5, for example. When a tip 2 is inserted into one of the housings 8, the lower face 19 of the AFM probe 1 rests on the bottom 5 of the storage box. The housings 8 are sufficiently spaced so that the probes 1 are not in contact with each other when they are stored in the storage box. A storage box may include twenty housing 8, for example. The housings 8 are evenly distributed and spaced apart in the bottom 5 of the base 4. The holding means and the housings 8 are configured so that a liquid can come into contact with the probe tips inserted in the housing 8. The housings 8 are wide enough to let the liquid pass. 25 The storage box comprises a cover 9 adapted to close and clear the storage space 7. The storage box comprises holding means able to block the probes 1 in the storage space 7 when the tips of the probes 1 are positioned in their respective slots 8. The storage box also includes sealing means 15 for sealing the liquid storage space 7 when the storage space 7 is closed by the cover 9 and filled with a liquid. The means for sealing the storage space 7 comprises a flat gasket disposed between the base 4 and the cover 9.

The cover 9 is configured to screw onto the base 4. The cover 9 includes a side wall 26 having a threaded portion 27 within the cover 9, and at its lower end. The cover 9 is screwed onto a threaded portion 28 of the side wall 6 of the base 4. This threaded portion 28 is positioned outside the base 4. When the cover 9 is screwed onto the base 4, the seal 15 is found again compressed between the cover 9 and the base 4. More specifically, the seal 15 is compressed between an upper peripheral edge 24 of the side wall 6 of the base 4, and a lower peripheral edge 25 of the side wall of the cover 9 The means The holding means comprise a bearing element 10 cooperating with locking means so that the bearing element 10 is able to exert pressure on all the probes. 1 to keep them locked against the bottom 5 of the base 4. The support element 10 has a flat bearing surface on its underside. The dimension of the support element 10 is adapted so that the latter can cover all the housings 8 of the base 4. The diameter of the support element 10 is close to the internal diameter of the base 4. When the support member 10 covers the upper face 20 of the probes 1, that is to say when it is locked position, its weight makes it possible to maintain the probes 1 partially blocked against the bottom 5 of the base 4. L The bearing element 10 comprises a protuberance 17 projecting from its upper surface 30. The cover 9 is adapted, when it is closed on the base 4, to exert pressure on the support element 10 by means of the protrusion 17, to completely block the probes against the bottom 5 of the base 4. Advantageously, the cover 9 comprises an upper inner wall 29 provided with a recess 18 for receiving the end of the protuberance 17 of the element support 10, to wedge the latter. The protrusion 17 is positioned in the center of the support element 10, and the recess 18 is positioned in the center of the upper wall 29 of the cover 9.

Thus, when the lid is closed, the support element 10 is centered with respect to the base 4. It always occupies the same position in the base 4. Preferably, the support element 10 is screwed on the base 4. For this, it comprises a threaded side wall screwing on the side wall of the base which is also threaded. Alternatively, the support element 10 comprises a threaded rod on its lower part which is screwed into a threaded hole formed in the bottom of the base 4. The base 4, the cover 9 and the support element 10 are constituted a material that does not present a risk of contamination of the tip of the AFM probe, and which is inert vis-à-vis the treatment and cleaning liquids. The base 4, the cover 9 and the support element 10 are made of the same materials as those mentioned in the first embodiment. Figure 7 shows a storage box for AFM probes 1, according to a third possible embodiment of the invention. The storage box comprises a base 4 having a bottom 5 and a side wall 6 defining a storage space 7. The bottom 5 comprises a housing 8 adapted to receive the tip 2 of a probe 1 to store it in the storage box .

The base 4 comprises an outer body 4 ', and an inner body 4' movable relative to the outer body 4 'The inner body 4' comprises the bottom 5 and the side wall 6 defining the storage space 7 of the base 4 The inner body 4 "is adapted to be housed in the outer body 4 'to form the base 4. In the example of Figure 7, the outer body 4', and the inner body 4" of the base 4 are distinct , unlike the examples of Figures 2 to 6 in which the outer body 4 ', and the inner body 4 "form a single piece which is the base 4. In the example of Figure 7, the outer body 4', and the internal body 4 "have a cylindrical section. Other forms are possible.

The outer body 4 'comprises a cavity 35 intended to receive the internal body 4 "The cavity 35 is delimited by a side wall 36 and a bottom The storage box comprises locking means comprising a threaded rod 33 secured to the part The threaded rod 33 is adapted to be screwed into a threaded hole 13 'formed in the center of the inner body 4 "of the base 4.

The bearing element 10 has a stop 34 protruding from its upper surface 30. The cover 9 is adapted, when it is closed and when the threaded rod 33 is screwed into the threaded hole 13 'of the internal body 4 ", to exert pressure on the stop 34 to block the inner body 4 "in the outer body 4 ', and more precisely against the bottom 37 of the outer body 4', without play possible. In Figure 7, the support member 10 has the shape of a disc, and the stop 34 has a cylindrical shape. Other forms are possible. The outer body 4 'comprises sealing means 15 for sealing the liquid storage space 7 when the storage space 7 is closed by the cover 9 and filled with a liquid. Means for sealing the storage space 7 comprise a seal 15 disposed between the outer body 4 'and the cover 9. The seal 15 is an O-ring which is housed in a circular groove 21 formed in the side wall 36 of the outer body 4 ', on its upper part. When the lid 9 is closed, it compresses the seal against the outer body 4 'of the base 4, sealing the liquid storage box. The cover 9 can be locked by screwing on the outer body 4 'of the base 4. Preferably, the cover 9 is locked on the outer body 4' of the base 4 by means of threaded rods screwed into threaded holes 23 provided in the side wall 36 of the outer body 4 'of the base 4, as illustrated in Figure 7. The threaded rods are able to pass through the orifices 22 formed on the cover 9. Preferably, the threaded rods are in number three. When the threaded rods are inserted into the orifices 22 of the lid 9, butterfly nuts, for example, are attached to the threaded rods to lock the lid 9 against the outer body 4 'and against the upper face 40 of the stop 34. The lid 9 comprises a filling and emptying orifice 16 of the liquid, and a closure means 12 able to close the filling and emptying orifice 16 in a sealed manner. The closure means 12 is a threaded plug which can be tapered. The external body 4 'and internal 4 "of the base 4, the cover 9, the holding means 35, and the cover 9 are made of a material which does not present any risk of contamination of the tip of the AFM probe, and which is inert with respect to the treatment and cleaning liquids The entire storage box, except the seal 15, is made of a material as cited in the first embodiment.

The liquid can be injected into the storage space 7, and drained from the latter through the filling and emptying orifice 16, by means of a syringe for example. By means of the filling and emptying port 16, it is possible to purge the air from the storage space 7 by completely filling it with a liquid. Preferably, the abutment 34 of the support member 10 comprises two flow grooves 41 on its upper face 40 which intersect to form a hollow intersection 42. When the lid 9 is closed on the base, and a liquid is introduced into the filling and emptying orifice 16, the latter flows into the flow grooves 41 to fill the storage space 7. In the example of Figure 7, the inner body 4 "of the base 4 comprises a single housing 8 formed of a circular groove dug in the bottom 5 of the inner body 4". The groove is centered with respect to the threaded hole 13 'and runs along the side wall 6 of the inner body 4. Its depth and width are adapted to the dimensions of the probe tip 2. The internal body 4 "of the base 4 comprises recesses 43 distributed circumferentially around the threaded hole 13 'of the inner body 4 "and opening into the groove, the recesses 43 are located between the threaded hole 13' and the groove, they have an elongated shape and extend in portions of radius passing through the center of the threaded hole 13 ', they have dimensions adapted to receive the remainder of the probe formed by the lever 3 and the support 3', The lower face 19 of each probe rests in one of the recesses 43.

Thus, storage boxes for AFM probes for transporting the probes in a liquid medium, and the application of chemical treatments in liquid medium to these probes are obtained.

Claims (11)

REVENDICATIONS1. Storage box for AFM probes (1), each probe (1) comprising a tip (2) disposed on a lever (3) integral with a support (3 '), said box comprising: a base (4) having a bottom (5) and a side wall (6) delimiting a storage space (7), said bottom (5) comprising at least one housing (8) adapted to receive the tip (2) of a probe (1), - a cover (9) adapted to close and disengage said storage space (7), - holding means able to block the probes (1) in the storage space (7) when the tips of the probes (1) are positioned in their respective housings (8), characterized in that it comprises: - sealing means (15) for sealing the liquid storage space (7) when said storage space (7) is closed by the lid (9) and filled with a liquid. 2. Storage box according to claim 1, characterized in that the holding means are movable relative to the cover (9). 3. Storage box according to any one of claims 1 or 2, characterized in that the base (4), the cover (9) and the holding means are made of a material that does not present a risk of contamination the tip of the AFM probe, and which is inert vis-à-vis the treatment liquids and cleaning probes. 4. Storage box according to claim 3, characterized in that the materials suitable for the base (4), the lid (9) and the holding means are selected from polytetrafluoroethylene, and polytetrafluoroethylenes loaded with inert materials. 5. Storage box according to any one of claims 2 to 4, characterized in that the holding means comprise a support element (10) cooperating with locking means so that said support element ( 10) is able to exert pressure on all the probes (1) to keep them locked against the bottom (5) of the base (4), the support element (10) having a flat bearing surface, and the dimension of the support element (10) being adapted so that the latter can cover all of the housing (8) of the base (4). Storage box according to claim 5, characterized in that, the support element (10) having an upper surface (30), the support element (10) is provided with a protuberance (17). protruding from said upper surface (30), the lid (9) being adapted, when closed, to exert pressure on said support member (10) by means of said protrusion (17), to block the probes against the bottom (5) of the base (4). 7. Storage box according to claim 5, characterized in that the locking means comprise a screw (11) cooperating with a threaded hole (13) formed in the center of the base (4), the support element (10). ) having an orifice (14) at its center, the screw (11) being adapted to pass through the orifice (14) of the support element (10) and to screw into the threaded hole (13) of the base (4) to block the probes (1) between the support element (10) and the base (4). 8. Storage box according to claim 5, characterized in that the base (4) comprises an outer body (4 '), and an inner body (4 ") movable relative to the outer body (4'), said inner body (4 ") comprising said bottom (5) and said side wall (6) delimiting the storage space (7) of the base (4), and being able to be housed in said outer body (4 ') to form the base (4). 9. 5 10 10. 15 11. Storage box according to claim 8, characterized in that the locking means comprise a threaded rod (33) integral with the lower part of the support element (10), said threaded rod (33) being adapted to screw into a threaded hole (13 ') formed in the center of the inner body (4 ") of the base (4), the bearing element (10) having a stop (34) projecting from its upper surface (30). ), the cover (9) being adapted, when closed and when the threaded rod (33) is screwed into the threaded hole (13 ') of the inner body (4 "), to exert pressure on said stop (34); ) for locking the inner body (4 ") against the outer body (4 ') A storage box according to any one of claims 1 to 9, characterized in that the means for sealing (15) the storage space (7) includes a gasket (15) disposed between the base (4) and the lid (9) A storage box according to any one of claims 1 to 10, characterized in that it comprises a filling and emptying orifice (16) of the liquid, and a closing means (12) able to close off said filling and emptying orifice (16).