EP0641980A1 - Device for heat exchange with a fluid which is partially freezing - Google Patents

Abstract

The present invention relates to a device for heat exchange between a coolant fluid (1) undergoing vaporisation and a fluid (2) to be cooled which is undergoing freezing. According to the invention, the device comprises a duct (3) for the fluid to be cooled, a casing (7) which forms, around the duct (3), an enclosure (8) for passage of the coolant fluid, and a mechanical means (11) for separating the wall (6) of the duct (3) from any solid phase in the fluid to be cooled, which mechanical means (11) consists of a rotor (12) provided with flexible radial filaments (14). The invention applies in particular to obtaining homogeneous mixtures of water and of ice. <IMAGE>

Description

The present invention relates generally to any indirect heat exchange between, on the one hand a refrigerant or refrigerant, for example a refrigerant (for example ammonia) during vaporization, and on the other hand a fluid with cool, namely a liquid during cooling and / or partial freezing, excluding any setting or mass of said fluid, such as glycol, alcoholic or salty water, the crystallization point of which is less than 0 ° vs.

• au moins un conduit de circulation sous pression du fluide à refroidir, d'une entrée à une sortie opposée pour ledit fluide, et dont la paroi constitue une surface d'échange thermique, avec une face dite chaude au contact du fluide à refroidir, et une face opposée, dite froide, au contact du fluide frigorigène ;
• une enveloppe ménageant avec et autour dudit conduit de circulation une enceinte ou moyen de réception ou passage du fluide frigorigène, préférentiellement à contre-courant du fluide à refroidir, d'une entrée à une sortie pour ledit fluide frigorigène ;
• et un moyen mécanique antagoniste du dépôt sur la face chaude de la paroi du conduit, de toute couche solide du fluide en cours de refroidissement, ce moyen comportant un rotor monté au sein dudit conduit, et différents éléments antagonistes dudit dépôt, consistant chacun en un racleur au contact ou au voisinage de la face chaude de la paroi du conduit ; ces différents éléments dits antagonistes sont distribués selon l'axe et autour du rotor, et entraînés par un moyen moteur, monté à l'extérieur du conduit de circulation.

With regard to cooling with partial freezing of a liquid or fluid, so as to avoid solidification of the latter under the effect of its solidification, and to obtain a fluid consisting of a homogeneous mixture of the liquid and solid phases of the fluid , heat exchange devices known as "scraped surface" are already known and used, comprising:

• at least one pressurized circulation pipe for the fluid to be cooled, from an inlet to an opposite outlet for said fluid, and the wall of which constitutes a heat exchange surface, with a so-called hot face in contact with the fluid to be cooled, and an opposite face, called cold, in contact with the refrigerant;
• an envelope providing with and around said circulation duct an enclosure or means for receiving or passing the refrigerant, preferably against the current of the fluid to be cooled, from an inlet to an outlet for said refrigerant;
• and a mechanical means antagonistic to the deposition on the hot face of the wall of the conduit, of any solid layer of the fluid being cooled, this means comprising a rotor mounted within said conduit, and different antagonistic elements of said deposit, each consisting of a scraper in contact with or near the hot face of the wall of the duct; these different so-called antagonistic elements are distributed along the axis and around the rotor, and driven by a motor means, mounted outside the circulation duct.

• en faisant circuler un courant du fluide à refroidir, sous pression dans le conduit de circulation, en échange de chaleur indirect avec le fluide frigorigène, de part et d'autre de la paroi d'échange thermique, c'est-à-dire de la paroi dudit conduit, dont l'une des faces, dite chaude est au contact du fluide à refroidir, et dont l'autre face, dite froide est au contact du fluide frigorigène
• et en s'opposant, au moyen du rotor avec ses racleurs, au dépôt sur la face chaude de la paroi d'échange thermique, de toute couche solide du fluide à refroidir.

Such a heat exchange device, with a scraped surface, makes it possible to exchange heat between, on the one hand the refrigerant, for example during vaporization, and on the other hand the fluid to be cooled, during partial freezing, and this:

• by circulating a current of the fluid to be cooled, under pressure in the circulation duct, in exchange for indirect heat with the refrigerant, on either side of the heat exchange wall, that is to say of the wall of said duct, one of the so-called hot faces being in contact with the fluid to be cooled, and the other so-called cold face of which is in contact with the refrigerant
• and by opposing, by means of the rotor with its scrapers, the deposition on the hot face of the heat exchange wall, of any solid layer of the fluid to be cooled.

Today, scraped surface heat exchangers constitute devices of complicated structure and construction, and therefore of a non-negligible cost, in particular if the scrapers are pivotally mounted on the rotor, each with its own return means. .

The subject of the present invention is an alternative to scraped surface heat exchangers, which is much simpler as regards its construction and operation.

According to the present invention, in general, to oppose the deposition of any solid layer on the hot face of the heat exchange wall, there is created in the current of the fluid to be cooled, circulating in the above-mentioned pressurized circulation pipe. , and in contact with the hot face of the heat exchange wall, a turbulent boundary layer, sub-cooled in the liquid phase, and in direct heat exchange with the rest of the current of the fluid to be cooled.

To this end, the various antagonistic elements of the deposition of any solid layer of the fluid to be cooled, on the hot face of the heat exchange wall, comprise a multiplicity of flexible filaments, one end of which is integral with the rotor, and the another free end is adjacent, that is to say in contact with or in the vicinity but at a distance from the hot face of the heat exchange wall. In relation to the rotation of the rotor, the flexible filaments are arranged essentially to agitate in the liquid phase the boundary layer of the current of the fluid to be cooled, in contact with the hot face of the heat exchange wall, and in admixture with the rest of said fluid to cool.

By "sub-cooled" is meant the characteristic that the heat exchange fluid is brought into the liquid phase, that is to say without at least partial freezing, at a temperature below its crystallization point.

Thanks to the present invention, the formation of a turbulent boundary layer in contact with the hot face of the heat exchange wall has the effect that freezing takes place, not on the hot face of said wall, but within of the fluid to be cooled in circulation, immediately in the vicinity of said wall, by direct heat exchange, that is to say by mixing the turbulent and sub-cooled boundary layer, expelled from said hot face, with the rest of the fluid to cool.

As indicated above, this turbulent boundary layer is obtained, preferably, but not exclusively, by the vibratile effect, of agitation and / or homogenization of the free end of the flexible filaments, in rotation.

The intrinsic characteristics of these filaments, including the nature (in terms of flexibility and / or rigidity, resistance to low temperatures, etc.), as well as the arrangement of these different filaments, including density per unit area, are chosen, firstly according to the nature of the fluid to be cooled, and secondly the speed of rotation of the rotor, so as to obtain the turbulent boundary layer in phase liquid, characterizing the present invention.

The present invention also provides the following determining advantages.

Thanks to the direct heat exchange between the turbulent boundary layer and the rest of the fluid to be cooled, and / or under the action of the free end of the multiplicity of filaments, the freezing of the fluid to be cooled takes place by obtaining micro-crystals, that is to say solid phase crystals of dimensions much smaller than those of the crystals obtained with a scraped surface exchanger. Obtaining such micro-crystals promotes the homogeneity of the cooled fluid, that is to say of the mixture of the liquid and solid phases of said fluid. And these micro-crystals reduce or suppress the inertia when melting the cooled fluid, obtained in two-phase form, which appears extremely favorable when said fluid is then used in heat exchange processes, in particular refrigeration, with exchange of the latent heat of fusion of the solid phase of said fluid.

The present invention also makes it possible to reduce or limit the expenditure of energy required, in particular mechanical energy, to prevent or counteract the formation of any solid layer on the hot face of the heat exchange wall.

And the invention also makes it possible to increase the heat exchange coefficient of the fluid during cooling with respect to the heat exchange wall.

• lesdits éléments antagonistes sont séparés les uns des autres, en formant une pluralité d'organes filamentaires, notamment disposés axialement, et distribués selon l'axe et autour du rotor ; ou lesdits filaments constituent ensemble une hélice, continue ou discontinue, autour de l'axe du rotor ;
• le moyen d'entraînement du rotor consiste en un moteur monté à l'extérieur du conduit de circulation, et couplé au rotor de ce dernier ; ou il n'existe pas de moteur extérieur, et les moyens d'entraînement du rotor sont constitués par tout système ou agencement auto-moteur, entraînant ledit rotor sous l'effet moteur du fluide à refroidir passant dans le conduit de circulation ; ce système ou agencement auto-moteur peut d'ailleurs être appliqué à tout dispositif de refroidissement, tel que défini généralement dans le préambule de la présente description, conforme ou non à la présente invention
• les conduits de circulation peuvent être disposés en batterie, et à cette fin, le dispositif selon l'invention comprend une pluralité de conduits de circulation du fluide à refroidir, disposés en parallèle, et une enveloppe commune ménageant avec lesdits conduits une seule et même enceinte de passage du fluide frigorigène, un distributeur du fluide à refroidir dans les différents conduits de circulation, et un collecteur du fluide refroidi évacué des différents conduits de circulation ; dans ce cas, on fait circuler une pluralité de courants du fluide à refroidir, en échange de chaleur indirect avec le fluide frigorigène.

According to the present invention, preferably, but not exclusively, the following methods of execution can be retained:

• said opposing elements are separated from each other, forming a plurality of filamentary members, in particular arranged axially, and distributed along the axis and around the rotor; or said filaments together constitute a helix, continuous or discontinuous, around the axis of the rotor;
• the rotor drive means consists of a motor mounted outside the circulation duct, and coupled to the rotor of the latter; or there is no external motor, and the rotor drive means are constituted by any self-powered system or arrangement, driving said rotor under the motor effect of the fluid to be cooled passing through the circulation duct; this self-driving system or arrangement can moreover be applied to any cooling device, as generally defined in the preamble to this description, whether or not in accordance with the present invention
• the circulation conduits can be arranged in a battery, and for this purpose, the device according to the invention comprises a plurality of conduits for circulation of the fluid to be cooled, arranged in parallel, and a common envelope providing with said conduits a single and same enclosure for the passage of the refrigerant, a distributor of the fluid to be cooled in the various circulation conduits, and a collector of the cooled fluid discharged from the various circulation conduits; in this case, a plurality of currents of the fluid to be cooled are circulated in exchange for indirect heat with the refrigerant.

• la figure 1 représente, en coupe verticale, un dispositif d'échange de chaleur selon un mode d'exécution de l'invention ;
• la figure 2 représente, toujours en coupe transversale et verticale, un dispositif d'échange de chaleur selon un deuxième mode d'exécution de l'invention ;
• la figure 3 représente, en coupe longitudinale et verticale, un dispositif d'échange de chaleur selon un troisième mode d'exécution de l'invention ;
• la figure 4 représente, en coupe verticale, un dispositif d'échange de chaleur selon un quatrième mode d'exécution de l'invention ;
• la figure 5 représente le dispositif selon figure 4, en coupe selon la ligne V.V de cette dernière ;
• la figure 6 représente une vue en coupe d'un conduit de circulation appartenant au dispositif selon figures 4 et 5, selon la ligne de coupe VI.VI de la figure 4 ;
• la figure 7 représente un dispositif d'échange de chaleur selon un cinquième mode d'exécution de l'invention ;
• la figure 8 représente, en coupe axiale, un dispositif d'échange de chaleur selon un sixième mode d'exécution de l'invention ;
• la figure 9 représente, un dispositif d'échange de chaleur selon un septième mode d'exécution de l'invention, toujours en coupe axiale ;
• la figure 10 représente, en coupe axiale, un dispositif selon un huitième mode d'exécution de l'invention ;
• la figure 11 représente une vue de dessus du rotor appartenant au dispositif selon figure 10 ;
• les figures 12 à 14 explicitent, dans des plans transversaux respectivement superposés, la relation angulaire existant entre le tube fixe du rotor d'un dispositif selon figure 10, et respectivement trois paires de bras radiaux superposés, mais décalés angulairement les uns par rapport aux autres.

The present invention is now described with reference to the accompanying drawing, in which:

• Figure 1 shows, in vertical section, a heat exchange device according to an embodiment of the invention;
• Figure 2 shows, still in transverse and vertical section, a heat exchange device according to a second embodiment of the invention;
• Figure 3 shows, in longitudinal and vertical section, a heat exchange device according to a third embodiment of the invention;
• Figure 4 shows, in vertical section, a heat exchange device according to a fourth embodiment of the invention;
• Figure 5 shows the device according to Figure 4, in section along the line VV of the latter;
• 6 shows a sectional view of a circulation duct belonging to the device according to Figures 4 and 5, along the section line VI.VI of Figure 4;
• FIG. 7 represents a heat exchange device according to a fifth embodiment of the invention;
• FIG. 8 represents, in axial section, a heat exchange device according to a sixth embodiment of the invention;
• FIG. 9 represents a heat exchange device according to a seventh embodiment of the invention, still in axial section;
• FIG. 10 represents, in axial section, a device according to an eighth embodiment of the invention;
• Figure 11 shows a top view of the rotor belonging to the device according to Figure 10;
• FIGS. 12 to 14 explain, in respectively superimposed transverse planes, the angular relationship existing between the fixed tube of the rotor of a device according to FIG. 10, and respectively three pairs of radial arms superimposed, but angularly offset with respect to each other .

• un conduit 3 droit, disposé verticalement, pour la circulation sous pression du fluide 2 à refroidir, d'une entrée 4 située au bas du conduit 3, à deux sorties 5 opposées, situées au haut du conduit 3 ; c'est la paroi métallique 6 du conduit 3 qui constitue la surface d'échange thermique entre le fluide frigorigène 1, du côté de sa face dite froide 6b, et le fluide à refroidir 2, du côté de sa face dite chaude 6a ;
• une enveloppe 7, rapportée sur le conduit 3, ménageant avec et autour de ce dernier, une enceinte ou moyen de passage du fluide frigorigène 1, à contre-courant du fluide 2 à refroidir, d'une entrée haute 9 à une sortie basse 10 ;
• un moyen mécanique 11 antagoniste du dépôt, sur la face chaude 6a de la paroi 6 d'échange thermique, de toute couche solide du fluide à refroidir.

In accordance with FIG. 1, the device according to the invention makes it possible to exchange heat indirectly between, on the one hand, a refrigerant 1, for example of ammonia in the course of vaporization, and on the other hand, a fluid 2 to be cooled, for example water whose freezing point has been lowered (for example glycol, alcoholic or salty water), in the course of freezing or partial crystallization. This device includes:

• a straight duct 3, arranged vertically, for the pressurized circulation of the fluid 2 to be cooled, from an inlet 4 located at the bottom of the duct 3, with two opposite outlets 5, located at the top of the duct 3; it is the metal wall 6 of the conduit 3 which constitutes the heat exchange surface between the refrigerant 1, on the side of its so-called cold face 6b, and the fluid to be cooled 2, on the side of its so-called hot face 6a;
• a casing 7, attached to the duct 3, providing with and around the latter, an enclosure or means for the passage of the refrigerant 1, counter-current to the fluid 2 to be cooled, from a high inlet 9 to a low outlet 10 ;
• a mechanical means 11 antagonistic of the deposition, on the hot face 6a of the wall 6 of heat exchange, of any solid layer of the fluid to be cooled.

• un rotor 12 monté au sein du conduit 3 ;
• une pluralité d'organes filamentaires 15, disposés axialement, en étant distribués selon l'axe et autour du rotor 12, et comportant chacune une multiplicité de filaments 14 radiaux et souples, formant des éléments antagonistes 13 du dépôt de toute couche solide sur la face chaude 6a de la paroi du conduit 3 ; ces filaments 14 peuvent être obtenus par exemple en toute matière synthétique, relativement souple et rigide à la fois, par exemple à partir de fils de polyamide ; chaque filament 14 a une extrémité solidaire du rotor, et l'autre extrémité libre adjacente à la paroi du conduit de circulation, c'est-à-dire au contact ou au voisinage immédiat de la face chaude 6a du conduit 6 ;
• et un moyen 40 d'entraînement du rotor 12 équipé des organes filamentaires 15.

According to the invention, this mechanical means 11 comprises:

• a rotor 12 mounted within the conduit 3;
• a plurality of filamentary members 15, arranged axially, being distributed along the axis and around the rotor 12, and each comprising a multiplicity of radial and flexible filaments 14, forming antagonistic elements 13 from the deposition of any solid layer on the face hot 6a of the wall of the conduit 3; these filaments 14 can be obtained for example from any synthetic material, relatively flexible and rigid at the same time, for example from polyamide yarns; each filament 14 has one end integral with the rotor, and the other free end adjacent to the wall of the duct circulation, that is to say in contact with or in the immediate vicinity of the hot face 6a of the duct 6;
• and a means 40 for driving the rotor 12 equipped with the filamentary members 15.

As shown in Figure 1, the filamentary members 15 are separated from each other, being at the same time, superimposed in groups of two, and offset angularly with respect to the axis of the rotor, for example at an angle of 90 ° or 60 °, from one group to another, and this from one end to the other of the circulation duct 3. And two filamentary members 15 of the same group are arranged opposite in a single and same diametrical plane.

The rotor drive means 40 consists of a motor 17 mounted outside of the circulation duct 3, and coupled to the rotor 12 by any suitable means, for example a gear motor.

• on fait circuler, sous pression, un courant du fluide 2 à refroidir, dans le conduit 3, en échange de chaleur indirect avec le fluide frigorigène 1, lesdits fluides étant respectivement de part et d'autre de la paroi 6 d'échange thermique. La face chaude 6a de la paroi 6 est au contact du fluide à refroidir, tandis que l'autre face froide 6b de la même paroi 6 est au contact du fluide frigorigène 1 ;
• grâce au moyen mécanique 11, constitué comme décrit précédemment par le rotor 12 et sa pluralité d'organes filamentaires 15, et au moyen 40 d'entraînement, on crée dans le courant du fluide 2 à refroidir, et au contact de la face chaude 6a de la paroi 6 du conduit 3, une couche limite turbulente, sous-refroidie en phase liquide, et en échange de chaleur direct avec le reste du courant du fluide à refroidir.

With the exchanger previously described with reference to FIG. 1, heat is exchanged between, on the one hand the refrigerant 1 during vaporization, in the enclosure formed between the casing 7 and the conduit 3, and d on the other hand the fluid to be cooled, circulating under pressure in the conduit 3, during partial freezing, to the exclusion of any solidification of said fluid, in particular by depositing a solid layer on the hot face 6a of the wall metallic 6. To this end:

• a current of the fluid 2 to be cooled is circulated under pressure in the conduit 3, in indirect heat exchange with the refrigerant 1, said fluids being respectively on either side of the wall 6 of heat exchange. The hot face 6a of the wall 6 is in contact with the fluid to be cooled, while the other cold face 6b of the same wall 6 is in contact with the refrigerant 1;
• by mechanical means 11, constituted as described above by the rotor 12 and its plurality of members filamentary 15, and by means of drive 40, a turbulent boundary layer, sub-cooled in liquid phase, is created in the stream of fluid 2 to be cooled, and in contact with the hot face 6a of the wall 6 of the conduit 3 and in exchange for direct heat with the rest of the stream of fluid to be cooled.

Thus, not only is it opposed to the deposition on the hot face 6a of the wall 6, of any solid layer of the fluid to be cooled, but also it promotes direct and homogeneous mixing of said layer with the rest of the current of the fluid to be cooled , by forming micro-crystals of solid phase, which are entrained and discharged in the current, without possibility of adhesion or deposit on the hot face 6a of the above-mentioned wall 6.

The embodiment shown in FIG. 2 differs from that previously described, by the mode of driving the rotor 12.

According to FIG. 2, the rotor is driven, with a means 18 acting under the driving effect of the fluid 2 to be cooled, passing through the circulation duct 3.

• le rotor 12 est creux, et aménagé pour une circulation axiale du fluide 2 à refroidir, préalable à sa circulation dans le conduit 3, d'une entrée axiale 21, du côté de l'entrée 4 dans le conduit de circulation, à une sortie opposée 22 d'introduction du fluide, par retour dans le conduit 3 proprement dit, entre ce dernier et le rotor 12 ;
• un moyen moteur 23, sous l'effet du fluide 2 circulant à l'intérieur du rotor 12, est monté dans ce dernier et calé en rotation sur ledit rotor ; selon ce mode d'exécution, ce moyen moteur 23 consiste en une hélice 24 coaxiale au rotor 12, comportant un noyau axial 25 et une aile 26 hélicoïdale reliant ce dernier et la paroi 27 du rotor, en ménageant un canal 28 hélicoïdal de circulation du fluide 2 à refroidir.

In accordance with FIG. 2, this means 18 is obtained by the combination of the following arrangements:

• the rotor 12 is hollow, and arranged for an axial circulation of the fluid 2 to be cooled, prior to its circulation in the duct 3, from an axial inlet 21, on the side of the inlet 4 in the circulation duct, to an outlet opposite 22 for introducing the fluid, by return to the conduit 3 proper, between the latter and the rotor 12;
• a motor means 23, under the effect of the fluid 2 circulating inside the rotor 12, is mounted in the latter and locked in rotation on said rotor; according to this embodiment, this drive means 23 consists of a propeller 24 coaxial with the rotor 12, comprising an axial core 25 and a helical wing 26 connecting the latter and the wall 27 of the rotor, providing a helical channel 28 for circulation of the fluid 2 to be cooled.

• les éléments antagonistes 13, ou multiplicité de filaments 14 radiaux et souples, constituent ensemble une hélice 16 continue, autour de l'axe 12, ce qui permet au surplus de transporter le fluide 2 à refroidir, à la manière d'une vis d'Archimède ;
• l'entraînement du rotor 12, sous l'effet moteur du fluide 2 à refroidir passant dans le conduit de circulation 3, est obtenu d'une autre manière ; plus précisément, une pluralité de pales 19 sont montées sur le rotor 12, chacune s'étendant avec au moins une direction radiale, et présentant par rapport au fluide 2 en circulation, une surface antérieure opposant localement une résistance audit fluide ; comme le montre la figure 3, les pales sont distribuées et disposées dans l'interstice 20, délimité par l'hélice radiale 16.

The embodiment of FIG. 3 differs from those described with reference to FIGS. 1 and 2, by the following technical characteristics:

• the opposing elements 13, or multiplicity of radial and flexible filaments 14, together constitute a continuous helix 16, around the axis 12, which allows the surplus to transport the fluid 2 to be cooled, in the manner of a screw Archimedes;
• the drive of the rotor 12, under the driving effect of the fluid 2 to be cooled passing through the circulation duct 3, is obtained in another way; more specifically, a plurality of blades 19 are mounted on the rotor 12, each extending with at least one radial direction, and having, with respect to the fluid 2 in circulation, a front surface locally opposing a resistance to said fluid; as shown in FIG. 3, the blades are distributed and arranged in the gap 20, delimited by the radial propeller 16.

The embodiment described with reference to FIGS. 4 to 6 differs from those described above, in that the conduits 3 for circulation of the fluid to be cooled are arranged in a battery. To this end, there is therefore a plurality of conduits 3, arranged in parallel, and one and the same common envelope 7, cylindrical for example, providing with the conduits 3, one and the same enclosure 8 for the passage of the refrigerant. At the top and at the bottom of the device, there is respectively a distributor 29 of the fluid 2 in the various conduits 3, and a collector 30 of the cooled fluid 2 discharged from the various conduits 3, this distributor and this collector being separated and sealed with respect to the 'enclosure 8 for the passage of the refrigerant.

Furthermore, one and the same motor 17 is coupled by a transmission means 31 to the various rotors 12 of the various circulation conduits 3.

The embodiment shown in Figure 7 includes a battery of conduits 3, as previously described with reference to Figures 4 to 6. But in this case, and as already described with reference to Figure 2, the motor 17 has been deleted in favor of motor means 23 integrated in the rotors 12, and acting under the sole effect of the circulation of the fluid 2. To this end, the distributor 29 of the fluid to be cooled communicates only with the different axial inlets 21 of the hollow rotors 12 of the different traffic conduits 3 respectively.

• 1) Une pluralité de capacités 41 de passage du fluide frigorigène sont disposées en parallèle, coaxialement à l'axe du rotor 12 et de manière étagée dans le conduit 3 de circulation du fluide à refroidir ; chaque capacité 41 comprend deux cloisons 42 et 43 d'extension radiale, formant chacune un élément de la paroi 6 d'échange thermique entre le fluide à refroidir et le fluide frigorigène ; en pratique, et comme représenté à la figure 8, chaque capacité 41 consiste en un élément circulaire, creux et aplati, évidé en son centre, ayant généralement la forme d'un disque, et dont les deux faces planes 42 et 43 constituent respectivement les deux cloisons d'échange thermique précitées.
• 2) Un distributeur 44 du fluide frigorigène, en relation avec l'entrée 9 pour ledit fluide, et un collecteur 45 du même fluide, en relation avec la sortie 10 pour ce dernier, sont disposés à l'extérieur du conduit 3 de circulation, et communiquent avec la pluralité des capacités 41 de passage identifiées précédemment.
• 3) Une pluralité de bras 46 et 47, chacun d'extension radiale, sont solidaires du rotor 12, et disposés chacun entre deux capacités 41 de passage du fluide frigorigène, ou entre une dite capacité et une extrémité du conduit 3 de circulation.
• 4) Une pluralité d'organes filamentaires 15, tels que définis précédemment, sont montés sur la pluralité des bras 46 et 47, en étant orientés chacun radialement ; en conséquence, les différents filaments souples 14 des organes 15 sont dirigés individuellement selon une direction axiale, avec leurs extrémités libres adjacentes à la face chaude 6a des différentes cloisons radiales 42 et 43 d'échange thermique, identifiées précédemment.

The exchange device represented according to FIG. 8 differs from those described above, by the following technical characteristics:

• 1) A plurality of capacities 41 for the passage of the refrigerant are arranged in parallel, coaxial with the axis of the rotor 12 and in a stepped manner in the conduit 3 for circulation of the fluid to be cooled; each capacity 41 comprises two partitions 42 and 43 of radial extension, each forming an element of the wall 6 of heat exchange between the fluid to be cooled and the refrigerant; in practice, and as shown in FIG. 8, each capacity 41 consists of a circular, hollow and flattened element, hollowed out at its center, generally having the shape of a disc, and the two flat faces 42 and 43 of which constitute respectively two aforementioned heat exchange partitions.
• 2) A distributor 44 of the refrigerant, in relation to the inlet 9 for said fluid, and a manifold 45 of the same fluid, in relation to the outlet 10 for the latter, are arranged outside the conduit 3 of circulation, and communicate with the plurality of passage capacities 41 identified previously.
• 3) A plurality of arms 46 and 47, each of radial extension, are integral with the rotor 12, and each disposed between two capacities 41 for the passage of the refrigerant, or between a said capacity and one end of the circulation conduit 3.
• 4) A plurality of filamentary members 15, as defined above, are mounted on the plurality of arms 46 and 47, each being oriented radially; consequently, the various flexible filaments 14 of the members 15 are directed individually in an axial direction, with their free ends adjacent to the hot face 6a of the various radial partitions 42 and 43 of heat exchange, identified previously.

As regards the filamentary members 15, these are superimposed in pairs, possibly being angularly offset from one pair to the other, as shown more particularly in FIGS. 10 to 14.

As regards the two filamentary members 15 belonging to the same pair, these are arranged in the same diametral plane. And, between two capacities 41, the same arm 46 or 47 of radial extension carries two filamentary members 15 opposite one with respect to the other, in relation to the two hot faces 6a of two exchange partitions 42 and 43 thermal, belonging respectively to the two abovementioned capacities 41, that is to say facing one another.

• le rotor 12 est creux, avec des passages 48 vers l'intérieur du conduit 3, ménagés au travers de sa paroi, et étagés entre les différentes capacités 41 de passage du fluide frigorigène, ceci pour permettre la circulation du fluide à refroidir, d'une extrémité ouverte 49 à une extrémité fermée 50 du rotor 12 ;
• et une boîte 51 d'introduction du fluide à refroidir est seulement en relation avec l'extrémité ouverte 49 du rotor creux 12, et l'entrée 4 pour le fluide à refroidir 2.

Still according to FIG. 8, the fluid to be cooled 2 is introduced into the exchange device, thanks to the following arrangements:

• the rotor 12 is hollow, with passages 48 towards the inside of the duct 3, formed through its wall, and stepped between the various capacities 41 for the passage of the refrigerant, this to allow the circulation of the fluid to be cooled, from an open end 49 to a closed end 50 of the rotor 12;
• and a box 51 for introducing the fluid to be cooled is only in relation to the open end 49 of the hollow rotor 12, and the inlet 4 for the fluid to be cooled 2.

• une pluralité d'orifices 52 sont ménagés dans la paroi 3, en étant étagés respectivement en relation avec les différents interstices entre les capacités 41 de passage du fluide frigorigène ;
• et un carter 53 d'évacuation du fluide refroidi est en relation, d'une part avec tous les orifices 52 du conduit 3, et d'autre part avec la sortie 5 du fluide refroidi.

Furthermore, the evacuation of the cooled fluid is obtained by the following arrangements:

• a plurality of orifices 52 are formed in the wall 3, being staged respectively in relation to the different interstices between the capacities 41 for the passage of the refrigerant;
• and a casing 53 for evacuating the cooled fluid is in relation, on the one hand with all the orifices 52 of the conduit 3, and on the other hand with the outlet 5 of the cooled fluid.

The embodiment according to FIG. 9 differs from that described according to FIG. 8, essentially by the presence of vanes 54 for driving the rotor 12, under the driving effect of the fluid 2 to be cooled in circulation, distributed radially in the box 51 of introduction of said fluid.

Finally, the last embodiment of the invention, according to Figures 10 to 14 differs from those described with reference to Figures 8 and 9, by the following different characteristics.

• la disposition sur le conduit 3 d'un tube fixe 55, coaxial au rotor creux 12, comportant une extrémité 56 ouverte pour l'entrée 4 du fluide à refroidir, des passages 55a et 55b (cf figures 12 à 14) d'évacuation du fluide à refroidir vers le rotor 12, et une autre extrémité fermée 57 ; par construction, le rotor 12 est susceptible de tourner de manière relativement étanche par rapport au tube fixe 55 ;
• les différents bras 46 et 47 radiaux creux, communiquent avec l'intérieur du rotor 12 et les passages précités 55a et 55b d'évacuation du tube fixe 55, et comportent à leur extrémité libre un moyen 58, tel qu'une buse d'éjection du fluide à refroidir dans le conduit 3. Ensuite, les bras 46 et 47 radiaux, sont alignés diamétralement par paires disposées de manière étagée selon l'axe du conduit 3 (cf les paires A, B, C représentées aux figures 11 à 14). Pour les deux bras 46 et 47 d'une même paire, par exemple A, les moyens 58 d'éjection sont opposés, de manière à permettre une rotation du rotor 12, sous l'effet des jets éjectés par les moyens 58 d'une même paire de bras.

First of all, self-motor means for driving the rotor 12 are obtained by the combination of the following arrangements:

• the provision on the conduit 3 of a fixed tube 55, coaxial with the hollow rotor 12, comprising an open end 56 for the inlet 4 of the fluid to be cooled, passages 55a and 55b (cf. FIGS. 12 to 14) for discharging the fluid to be cooled towards the rotor 12, and another closed end 57; by construction, the rotor 12 is capable of rotating relatively tightly relative to the fixed tube 55;
• the various hollow radial arms 46 and 47 communicate with the interior of the rotor 12 and the aforementioned passages 55a and 55b for evacuating the fixed tube 55, and comprise at their free end a means 58, such as an ejection nozzle of the fluid to be cooled in the duct 3. Next, the radial arms 46 and 47 are aligned diametrically in pairs arranged in a staggered fashion along the axis of the duct 3 (cf. the pairs A, B, C shown in FIGS. 11 to 14) . For the two arms 46 and 47 of the same pair, for example A, the ejection means 58 are opposite, so as to allow rotation of the rotor 12, under the effect of the jets ejected by the means 58 of a same pair of arms.

Finally, as best shown in FIGS. 12 to 14, the pairs of radial arms 46 and 47, for example A to C, are angularly offset with respect to each other, at a predetermined angle, for example 60 °, and this according to the same direction of rotation, clockwise or counterclockwise. In correspondence, the fixed tube 55 has two perforations 55a and 55b, axially elongated, and opposite. The angular dimension of each perforation 55a or 55b is identical to the predetermined angle of offset from one pair to the other, for example 60 °. Such an arrangement makes it possible not to eject the fluid to be cooled by all the radial arms 46 and 47 of the rotor 12, but successively in groups of pairs A, B and C respectively. In other words, the pairs A, B and C successively eject in turn the fluid to be cooled; and during the ejection of said fluid by a pair B for example, the pairs C and A are inactive.

Claims (14)

1) A method of heat exchange between, on the one hand a refrigerant (1), for example during vaporization, and on the other hand a fluid to be cooled (2), during partial freezing, exclusion of any solidification of said fluid, according to which: - At least one current of the fluid (2) to be cooled is circulated, under pressure, in exchange for indirect heat with the refrigerant, respectively on either side of a wall (6) of heat exchange, of which l one of the faces, called hot (6a) is in contact with the fluid (2) to be cooled, and the other face of which, called cold (6b) is in contact with the refrigerant, - by mechanical means (11), the deposition on the hot face (6a) of the wall (6) of heat exchange, of any solid layer of the fluid to be cooled, characterized in that, in order to oppose the deposition of any solid layer on the hot face (6a) of the wall (6) of heat exchange, fluid (2) to be cooled is created in the current, and in contact with said hot face (6a), a turbulent boundary layer, sub-cooled in the liquid phase, and in direct heat exchange with the rest of the stream of the fluid to be cooled. 2) A heat exchange method according to claim 1, characterized in that a plurality of fluid streams (2) to be cooled are circulated, in indirect heat exchange with the refrigerant (1). 3) heat exchange device between, on the one hand a refrigerant (1), for example during vaporization, and on the other hand a fluid to be cooled (2), during partial freezing, said device comprising : - at least one duct (3) for pressurized circulation of the fluid (2) to be cooled, from an inlet (4) to a opposite outlet (5) for said fluid, comprising a heat exchange wall (6), one of the faces of which, called hot (6a), is in contact with the fluid (2) to be cooled; a means (8) for the passage of the refrigerant, in contact with the other, so-called cold (6b) face, of the heat exchange wall (6), - a mechanical means (11) antagonistic of the deposition on the hot face (6a) of the wall (6) of heat exchange, of any solid layer of the fluid to be cooled, comprising a rotor (12) mounted within the duct (3 ), antagonistic elements of said deposit, each in contact with or in the vicinity of the hot face (6a) of the wall (6) of heat exchange, distributed along the axis and around the rotor (12), as well as a means (40) training of the latter characterized in that said antagonistic elements (13) comprise a multiplicity of flexible filaments (14), one end of which is integral with the rotor (12), the other free end of which is adjacent to the hot face (6a) of the wall ( 6) heat exchange, and arranged in relation to the rotation of the rotor, essentially for agitating in liquid phase the boundary layer of the flow of the fluid (2) to be cooled, in contact with the hot face (6a) of the wall (6 ) heat exchange 4) Device according to claim 3, characterized in that the circulation duct (3) constitutes the wall (6) heat exchange, an envelope (7) household with and around the duct (3) an enclosure (8) of passage of the refrigerant, in particular against the current of the fluid to be cooled, and the flexible filaments (14) individually have at least one radial extension. 5) Device according to claim 3, characterized in that the filaments (14) are separated from each other, forming a plurality of filamentary organs (15). 6) Device according to claim 3, characterized in that, from one end to the other of the conduit (3) for circulation, the filamentary members (15) are superimposed in groups of two, being angularly offset with respect to the rotor axis, from one group to another. 7) Device according to claim 6, characterized in that, for each group, the two filamentary members (15) are arranged in the same diametral plane. 8) Device according to claim 6, characterized in that a group of filamentary members (15) is angularly offset by 90 ° or 60 °, relative to the following. 9) Device according to claim 4, characterized in that the filaments (14) together constitute a helix (16), continuous or discontinuous, around the axis of the rotor (12). 10) Device according to claim 3, characterized in that it comprises means (18) for driving the rotor (12), acting under the motor effect of the fluid (2) to be cooled passing through the circulation duct (3 ). 11) Device according to claim 4, characterized in that it comprises a plurality of conduits (3) for circulation of the fluid to be cooled, arranged in parallel, and a common casing (7) providing with said conduits a single and same enclosure ( 8) for the passage of the refrigerant, a distributor (29) of the fluid to be cooled in the various circulation conduits (3), and a collector (30) of the cooled fluid discharged from the various circulation conduits. 12) Device according to claim 3, characterized in that, firstly a plurality of capacities (41) for the passage of the refrigerant are arranged in parallel, coaxial with the axis of the rotor (12) and in a stepped manner in the duct (3 ) circulation of the fluid to be cooled, each capacity comprising at least one partition (42,43) of radial extension, forming an element of the wall (6) of heat exchange, secondly, a distributor (44) of the refrigerant, in relation to the inlet (9) for said fluid, and a manifold (45) for said refrigerant, in relation to the outlet (10) for said fluid, arranged in particular outside the circulation conduit (3), communicate with the plurality of capacities (41) for the passage of the refrigerant, and thirdly the flexible filaments (14) individually have at least one axial extension, with their free end adjacent to the hot face (6a) of a radial partition of a ability é (41). 13) Device according to claim 12, characterized in that each capacity (41) for the passage of the refrigerant consists of a circular element, hollow and flattened, hollowed out in its center, generally having the shape of a disc, the two faces of which planes (42,43) respectively constitute two heat exchange partitions. 14) Device according to claim 12, characterized in that it comprises a means for introducing the fluid to be cooled, comprising the following arrangements: - A hollow rotor (12), with passages (48) towards the inside of the duct (3), formed through its wall, and stepped between the capacities (41) for the passage of the refrigerant, for the circulation of the fluid cooling from an open end (49) to a closed end (50) of said rotor; - A box (51) for introducing the fluid to be cooled, in relation to the open end (49) of the hollow rotor (12).

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