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    • 专利摘要:
    The invention relates to a method for manufacturing heat exchangers with at least two fluid circuits each having channels from grooved plates. In this process according to the invention, elementary modules of exchangers, each of them each previously produced by diffusion welding of grooved plates, are assembled.
    公开号:FR3044752A1
    申请号:FR1561906
    申请日:2015-12-07
    公开日:2017-06-09
    发明作者:Gall Isabelle Moro-Le;Julien Cigna;Emmanuel Rigal
    申请人:Commissariat a lEnergie Atomique CEA;Commissariat a lEnergie Atomique et aux Energies Alternatives CEA;
    IPC主号:
    专利说明:

    METHOD OF MAKING A HEAT EXCHANGER WITH AT LEAST TWO CIRCULATING CIRCUITS OF FLUID, LARGE NUMBER OF CHANNELS AND / OR LARGE DIMENSIONS
    Technical area
    The present invention relates to heat exchangers with at least two fluid circuits each having channels. The invention relates more particularly to a new manufacturing method for obtaining such exchangers with a large number of channels and / or large dimensions.
    The known heat exchangers comprise either one or at least two internal fluid circulation channel circuits. In the single-circuit heat exchangers, the heat exchange takes place between the circuit and a surrounding fluid in which it is immersed. In the exchangers with at least two fluid circuits, the heat exchange takes place between the two fluid circuits.
    It is known chemical reactors which implement a continuous process in which a small amount of co-reactants is simultaneously injected at the inlet of a first fluid circuit, preferably equipped with a mixer, and is recovered. the chemical product obtained at the outlet of said first circuit. Among these known chemical reactors, some include a second fluid circuit, usually called utility, whose function is to thermally control the chemical reaction, either by providing the heat necessary for the reaction, or on the contrary by removing the heat released by that -this. Such chemical reactors with two fluid circuits with utility are usually called reactor-exchangers.
    The present invention relates both to the production of heat exchangers with only heat exchange function that the realization of exchangers-reactors. Thus, by "heat exchanger with at least two fluid circuits", it is necessary to understand in the context of the invention, both a heat exchanger with a function of heat exchange only a reactor-exchanger.
    State of the art
    The heat exchangers, known as plate heat exchangers, have significant advantages over heat exchangers, known as tube heat exchangers, in particular their thermal performance and their compactness thanks to a ratio of the surface area to the heat exchange volume favorably. Student.
    The known tube exchangers are, for example, tube and shell exchangers, in which a bundle of upright or bent U-shaped or helical tubes is fixed on pierced plates and disposed inside a chamber called calender. In these tube and shell exchangers, one of the fluids circulates inside the tubes while the other fluid circulates inside the shell. These tube and shell exchangers have a large volume and are therefore of low compactness.
    The known plate heat exchangers are more compact and are obtained by stacking plates comprising channels and assembled together.
    In the same way, the reactors-exchangers, known as plates, have the advantage of a high compactness and high capacities of cooling and therefore of thermal control during chemical reactions. The latter are indeed often exothermic, and it is necessary to limit the rise in temperature in the reactive channels, ie where the chemical reaction occurs, in order to control the reaction from a thermal point of view, and also to limit aging. thermal catalysts sometimes present in the reactive channels.
    In all cases, the channels are generally made by stamping plates, where appropriate by adding strips folded in the form of fins or by machining grooves. The machining is carried out by mechanical means, for example by milling or by chemical means. Chemical machining is usually called chemical or electrochemical etching. The assembly of the plates together is intended to ensure the sealing and / or the mechanical strength of the exchangers, in particular the resistance to pressure of the fluids circulating inside. The assembly generally relates to a stack made by superimposing, in a regularly repeated sequence, plates of several types, each type corresponding to one of the fluid circuits, the stack may contain non-grooved separation plates.
    Several assembly techniques are known and are implemented depending on the type of plate heat exchanger desired. The assembly can thus be obtained by mechanical means, such as tie rods holding the stack tight between two thick plates and rigid disposed at the ends. The sealing of the channels is then obtained by crushing reported joints. The assembly can also be obtained by welding, generally limited to the periphery of the plates, which sometimes requires to insert, after welding, the heat exchanger in a calender to allow it to withstand the pressure of the fluids. The assembly can still be obtained by brazing, in particular for exchangers for which fins are added. The assembly can finally be obtained by diffusion welding (welding-diffusion).
    The last two techniques mentioned make it possible to produce exchangers that are particularly efficient in terms of mechanical strength. Indeed, thanks to these two techniques, the assembly is obtained not only at the periphery of the plates but also inside the exchanger.
    Plate heat exchangers assembled by diffusion welding have joints that are even more mechanically efficient than the joints of the brazed exchangers due to the absence of the solder required for brazing.
    Welding-diffusion consists of obtaining a solid state assembly by applying a hot force to the parts to be assembled during a given time. The applied force has a dual function: it allows the docking, that is to say the contacting of the surfaces to be welded, and facilitates the creep-diffusion removal of the residual porosity in the joints (interfaces).
    The force can be applied by uniaxial compression, for example using a press equipped with an oven or simply using masses arranged at the top of the stack of parts to be assembled. This process is commonly known as uniaxial diffusion welding and is applied industrially for the manufacture of plate heat exchangers.
    An important limitation of the uniaxial welding-diffusion process is that it does not allow any orientation joints to be welded with respect to the direction of application of the uniaxial compression force.
    Another alternative method overcomes this disadvantage. In this other method, the force is applied via a gas under pressure in a sealed enclosure. This process is commonly referred to as Hot Isostatic Compression (CIC). Another advantage of the CIC welding-diffusion process compared to the uniaxial diffusion-diffusion process is that it is more widely used on an industrial scale. Indeed, the CIC is also used for the batch processing of castings as well as for the compaction of powders.
    The presently known compact diffusion plate clad heat exchangers also have disadvantages which can be enumerated as follows.
    A first drawback is the manufacturing cost of the plates, in particular in the case of machined channel plates. Chemical etching certainly allows a certain reduction of cost compared to mechanical machining but which is quite relative: in fact, compared to a given length, the cost of a channel of a plate heat exchanger made by chemical etching is higher. to that of a tube exchanger. In addition, chemical etching has many disadvantages, such as insufficient dimensional accuracy, unfavorable rounding of the edges to diffusion welding or residual pollution of the surfaces to be joined by residues of the stripping and masking products used.
    The second drawback of plate heat exchangers lies in the importance of obtaining optimum sealing of each fluid circuit with respect to the other circuits and to the environment of the exchanger, mainly for security purposes. As a result, the manufacture of such an exchanger requires most of the time a surface state of the plates almost free of any defects. Defects initially present on the surface of the plates before manufacture of the exchanger may remain after manufacture and thus allow possible leakage of one of the fluids. Before manufacture, long and tedious surface checks of each sheet are then necessary to detect these defects, and many plates can be discarded if necessary. In addition, checking the tightness of the heat exchanger to at least two fluid circuits after manufacture is difficult to implement with current techniques. All of these control operations coupled with the scrapping of plates with defects can generate significant additional costs.
    Another disadvantage of compact plate heat exchangers is the difficulty in finding a good compromise between the mechanical strength of the interface joints obtained, the acceptable deformation of the channels and the grain magnification of the structural material.
    Indeed, in the uniaxial welding-diffusion process, it is possible to apply a low or very low value force which does not deform the channels, provided that the plates are in good contact with one another and that the small value of the force is compensated. by increasing the welding temperature for the removal of porosity at the interfaces. These conditions inevitably imply a magnification of the grain of the material which can become unacceptable with respect to its resistance to corrosion and its mechanical properties. In addition, in many applications, it is critical that the number of material grains located between two fluid circuits exceeds a minimum value to avoid the risk of leakage.
    This problem of the good compromise to be found is all the more crucial and important as the reactor size and / or the number of reactor channels increases.
    In the process of welding-diffusion by CIC, the stack of parts is previously encapsulated in a sealed container to prevent the gas from entering the interfaces formed by the surfaces to be welded. The gas pressure usually used is high, of the order of 500 to 2000 bar, typically 1000 bar. The minimum operating pressure of the industrial enclosures adapted to implement the CIC is between 40 and 100 bar. However, the joints welded at this pressure are less resistant than those obtained at higher pressure, for example at 1000 bar, all the other conditions being equal (material, temperature, surface condition, etc.). In addition, this pressure between 40 and 100 bar is still too important for high channel density plates, that is to say plates whose contact surface determined with an adjacent plate is small relative to the total surface area. related. Indeed, for this type of plate, even a pressure of a few tens of bar may be sufficient to cause unacceptable deformation of the channels.
    A possible solution may be to reduce the assembly temperature so that the material withstands the pressure better, but this again degrades the strength of the joints.
    Another possible solution may be to change the pattern of the channels to make the stack more pressure resistant, but this is to make the plate heat exchanger less compact.
    Finally, a possible solution is, after diffusion welding the heat exchanger under low pressure, to open the channels and submit it to a CIC cycle at high pressure, so as to complete the assembly. This solution only works if the welding quality during the first assembly is good enough and sealed interfaces have been obtained. It should be noted that the transmission of the welding force in a stack of grooved plates is uneven, whether it is the uniaxial diffusion welding process or the diffusion welding process by CIC. Indeed, the parts of the interfaces located under the grooves are subjected to a reduced welding force since it is transmitted only by the two ribs, or isthm, located on either side of each groove. Conversely, a high welding force is obtained with respect to the ribs. The quality of the interfaces may therefore vary from one place to another of the stack. FIG. 1 shows a stack of four grooved plates 11, 12, 13, 14 which undergo diffusion welding in order to assemble them together. As symbolized in this figure, the quality of transmission of the welding force at the interface 110 between the two plates 12, 13 varies depending on the different areas with or without the ribs or isthmus.
    In addition, this heterogeneity of transmission of the welding force during the manufacture of these heat exchangers can result in a heterogeneous deformation of the assembly at the end of the manufacturing process, a most important deformation occurring in the zones. having undergone the greatest efforts, and vice versa. In the particular case of reactor-exchanger fabrication, this difference in final geometry between the reactive channels is potentially very troublesome. Indeed, it leads to a difference in gas flow between the reactive channels, and therefore to a heterogeneous wear of the catalysts in the different channels. This can lead to the appearance of hot spots and thus induce a reactor with an unstable and unstable thermal behavior, which inevitably leads to a drop in reactor efficiency and / or premature deactivation of the catalyst.
    The deformation can be reduced by a decrease in the assembly temperature so that the material has a better mechanical strength. However, this amounts to degrading the resistance of the joints obtained after welding-diffusion.
    Another possible solution may be to change the geometry of the channels with a decrease in the dimensions of the channels and / or an increase in the dimensions of the isthmas between channels, in order to make the stack more resistant to pressure, but this amounts to making the less compact plate heat exchanger.
    As the deformation also depends on the width of the banks, which are the non-grooved areas located laterally on either side of the grooved area, and the thickness of the anvils, which are the non-grooved areas at the ends of the top and from the bottom of the stack, another solution for reducing the deformation consists in thickening these zones. This thickening must be all the more important as the exchanger is large.
    However, the accessible CIC enclosures have limited dimensions: for large heat exchangers, the limits of the equipment are quickly reached by increasing the dimensions of the isthmus or lateral banks of the exchangers.
    In addition, when it is necessary to treat a large volume of fluid, and therefore to multiply the number of reactive channels, it is always easier to have a single large reactor rather than to parallel several larger reactors. scaled down. In fact, on the one hand, it is difficult to perfectly balance the flow rates between the different reactors, and this can therefore result in the premature wear of the catalyst present in certain reactors compared to others and, on the other hand, the fluidic parallelization of several reactors necessarily implies the multiplication of tubing, valves, and other distribution and control components. This results in an increase in the price of the installation, as well as a noticeable loss of compactness of the final installation.
    However, if one seeks to manufacture plate reactors assemble by diffusion welding, it is notably because they have a much better compactness than that of conventional tube reactors, as mentioned in the preamble.
    In this context, to maintain maximum compactness of the exchanger and of the entire system, the installation of large banks and / or the insertion into the reactor of solid plates allowing better mechanical resistance to the pressure under pressure. high temperature (and therefore less deformation) during welding should be avoided because it inevitably leads to a reduction in the compactness of the reactor.
    Finally, it is not possible to significantly increase the number of plates to increase the number of channels in the exchanger. Indeed, if for example at pressure and temperature given during a CIC assembly cycle, the height of the channels at the center of the stack decreases, at the end of the assembly cycle, for example by 10%, then more the number of channels in the reactor height is important, and so is the total subsidence of the reactor height. As a result, the deformation of the corner channels increases with the number of stacked channels.
    This is shown diagrammatically in FIGS. 2A and 2B which show, in section and over a quarter of a stack, the deformations calculated for two geometries (of identical dimensions but with a number of different plates) subjected to the same cycle of CIC. It can be seen that: the collapse of the height of the exchanger 1 of FIG. 2A is greater than that of FIG. 2B which has a smaller number of channels 2 in the height; the corner channels 2 'are more deformed in the exchanger of FIG. 2A than in that of FIG. 2B.
    Until now, when large exchangers and / or large number of channels are manufactured, in order to further increase their compactness, we will seek to reduce the dimensions of the channels, those of the isthmus and banks. All of these trends point to an increase in channel deformation during CIC assembly.
    There is therefore a need to further improve the processes for producing heat exchangers of large dimensions and / or with a large number of channels, in particular with a view to limiting the deformation of the channels during the assembly of the plates constituting said exchangers, and without degrading the interfaces between plates or adversely affect the compactness of the exchangers.
    The object of the invention is to at least partially meet this need.
    Presentation of the invention
    To do this, the subject of the invention is a method for producing a heat exchanger with at least two fluid circuits each comprising channels, comprising the following steps: a / production of at least two elementary heat exchanger modules , the realization of each elementary module comprising the following steps: i / production of one or more elements of one of the two fluid circuits, said first circuit, each element of the first circuit comprising at least one metal plate having first grooves forming at least a portion of the channels of the first circuit; ii / producing one or more elements of at least one other fluid circuit, said second circuit, each element of the second circuit comprising at least one metal plate having second grooves forming at least part of the channels of the second circuit; iii / stacking the metal plates of the elements of the first and second circuits so as to form their channels; iv / soldering-diffusion joint between the element or elements of the first circuit and the element or elements of the second circuit, stacked on one another; b / modification of at least one of the elementary modules comprising a reduction of the width of at least one of the banks and / or the thickness of at least one of the anvils of at least one of the modules and optionally an opening of the channels of the first circuit and / or the second circuit to the outside; c / edge-to-edge positioning of the elementary modules of which at least one reduced, according to one of their longitudinal edges or one of their lateral edges; d / assembly of the interfaces between the edge-to-edge elementary modules, in order to obtain the exchanger in one-piece form.
    Thus, the invention consists in assembling elementary modules of exchangers themselves each previously produced by welding diffusion of grooved plates.
    For each elementary exchanger module important lateral edges may be used, possibly in the form of non-grooved edges in the plates or as independent tools added in the container. This results in an increase in the bearing surface, and therefore a decrease in the overall stress seen by the material, and consequently a decrease in the final deformation.
    Similarly, important anvils can be used at the beginning and end of stacking of at least one of the elementary modules, possibly in the form of additional non-grooved plates or in the form of independent tools added to the container. This results in an increase in the stiffness of the stack which prevents its deformation with respect to the grooved area during the CIC cycle.
    Once these elementary modules assembled by diffusion welding, the excess matter that represents the anvils and the banks is eliminated at least in part and the so-called reduced modules obtained are assembled together. This b / modification step with at least a reduction of dimensions of at least one of the elementary modules makes it possible to improve the compactness of the elementary modules.
    This gives a monobloc exchanger which can be large and / or with a large number of channels, which could not have been achieved at one time according to the methods of the state of the art because because of these large dimensions and / or the large number of channels, excessive deformation would have appeared at the levels of the channels after assembly by welding-diffusion.
    In step a /, preferably before stacking, that is to say before step iii /, it is possible advantageously to perform a step il / and iil / cleaning the plates of each element respectively of the first circuit and second circuit. The cleaning can be carried out for example using detergents or solvents.
    According to an advantageous embodiment, step iv / is carried out by applying a relatively low pressure hot isostatic compression (CIC) cycle to the sealed and degassed stack. This CIC cycle is designated here at relatively low pressure, since the pressures are lower than those of a CIC cycle designated at high pressure, i.e between 500 and 2000 bar, advantageously between 800 and 1200 bar.
    The typical DUC cycle typically involves simultaneous heating and pressurization, a temperature and pressure plateau followed by cooling and depressurization. This cycle is chosen in particular according to the material (s) of the plates constituting the elements of the first and second circuits. In particular, it is possible to choose the bearing temperature and the heating and pressurization (respectively cooling and depressurization) speeds, in particular taking into account the capacities of the CIC enclosure used.
    Thus, preferably, the CIC cycle according to step iv / is carried out according to the following characteristics taken alone or in combination: at a pressure of between 20 and 500 bar, preferably between 30 and 300 bar; the choice of the pressure results from a compromise between quality of welding to obtain and acceptable deformation of the channels; at a temperature between room temperature and 1100 ° C., preferably between 900 and 1100 ° C .; the temperature that is retained depends on the constituent material of the plates used, the maximum grain size allowed, and the quality of the desired junction; for a period of between 15 minutes and a few hours, preferably between 1 and 4 hours; the heating and pressurization times (respectively cooling and depressurization) depend on the characteristics and possibilities of the equipment (enclosure) used, they are usually several hours.
    According to a first variant, prior to this low-pressure CIC cycle, it is possible to carry out a step of sealing the periphery of the at least two metal plates of each element, then carrying out a step of degassing the inside of each sealed stack. through a hole opening at each interface between plates, a closing step of the opening opening. Degassing of the channels and the interface or interfaces is achieved by evacuation, through the orifice opening and it is closed.
    Alternatively, it is possible to insert each stack in a metal envelope, called a container, and then a step of welding the container, which has an opening opening opposite which a tube, said tube is welded, a degassing step to through the queuing and then welding the exhaust pipe. To carry out the degassing, this tube is connected to a vacuum pump, the pumping is performed at a given temperature, between room temperature and 400 ° C, then the tube is sealed by welding, without re-airing. The duration of the pumping will depend on the desired vacuum quality.
    During step b /, the reduction of the width of at least one of the banks and / or the thickness of at least one of the anvils of at least one of the modules can be achieved by removing the tools by demolding or machining, or machining the non-grooved edges of the plates and / or anvils. The opening of the channels can be performed by machining the ends of the module or drilling against the channels. The c / edge-to-edge positioning step may consist of one or other of the following variants: a stack of the elementary modules by the main faces of the end plates of the modules; an edge-to-edge alignment according to the length of the elementary modules; positioning a lateral edge of one of the elementary modules against a lateral edge of the other of the elementary modules.
    This step c / may implement the use of alignment pins or any other means intended to ensure correct positioning of the reduced modules so as to establish the desired final geometry, in particular to establish the continuity of the fluid circuit (s). . Step a1 can be carried out for example by electron beam welding, soldering or diffusion welding of the reduced modules between them. According to a preferred embodiment, this step d / consists of welding-diffusion by CIC. In this case, it is implemented with the following preferred steps: cleaning of the surfaces of the reduced elementary modules using, for example, solvents and / or detergents; sealing of the periphery of the interfaces of the reduced elementary modules, by for example by welding or inserting them into a welded container, - degassing of the interfaces between the elementary modules of which reduced, for example by means of one or more tubes welded (s) facing one or more orifice (s) opening on the interfaces or one or more tubes welded (s) facing one or more openings (s) formed in the wall of the container, the (s) valves being sealed welded to the end of degassing, - application of at least one hot isostatic compression cycle.
    In addition, according to a still preferred embodiment, the diffusion welding of the reduced elementary modules is performed during the high pressure cycle for finishing the welding of the internal interfaces of the elementary modules. This process generates a minimal additional cost, mainly related to the realization of seals between the elementary modules, for example by means of peripheral welds. For this, step b / comprises an opening of the channels of the first circuit and / or the second circuit. When it is possible to open both fluid circuits, only one cycle of high pressure CIC can be applied. When the positioning of the reduced elementary modules at the end of step c / allows only one circuit to be opened, which is the case when the other circuit opens into the interfaces between reduced elementary modules, the pressure of the CIC cycle must be limited so as not to deform the closed circuit. In this case, it can be opened at the end of this cycle of CIC and apply a second cycle with the two open circuits to perfect the assembly of the exchanger.
    In this embodiment, the transmission of the welding force is effected by the gas pressure not only at the interfaces between elementary modules but also by the interior of the channels of each of the modules. Thus, the welding force is particularly well distributed and the welding of the elementary modules together is guaranteed. The invention therefore makes it possible to manufacture exchangers with numerous channels and / or large dimensions, while obtaining a great compactness of both the monobloc exchanger and the overall final system and minimizing the additional cost compared to the processes of the state. of the art, since at most only one additional welding-diffusion step is necessary.
    An elementary module may comprise plates of different materials or all made of the same material, such as a stainless steel type 316L.
    The constituent material (s) of an elementary module may be identical to or different from that or those of another elementary module.
    The method according to the invention may preferably comprise a step e / final machining to finalize the monobloc exchanger. The invention also relates to a heat exchanger with at least two fluid circuits obtained according to the method as described above. The invention is advantageously used for manufacturing low cost industrial heat exchangers without high thermo-hydraulic requirements but with a high criticality of tightness, such as that which can be encountered in reactor-exchangers.
    DETAILED DESCRIPTION Other advantages and characteristics of the invention will emerge more clearly on reading the detailed description of exemplary embodiments of the invention, given by way of non-limiting illustration with reference to the following figures among which: FIG. 1 is a cross-sectional view of a heat exchanger module according to the state of the art produced by CIC, showing the different transmission zones of the welding force; FIGS. 2A and 2B are diagrammatic cross-sectional views of exchanger modules according to the state of the art produced by CIC according to the same CIC cycle, respectively of higher and lower stacking height, showing the deformation of channels of one of the fluid circuits as well as the collapse of the height of the modules; FIGS. 3A, 3B and 3C are perspective views of a metal plate intended to produce an elementary heat exchanger module according to the invention, respectively before making the grooves forming part of the fluid channels, with the grooves d one of the circuits on one of its main faces and with the grooves of the other circuits on the other of its main faces; FIG. 4 is a perspective view of an exemplary elementary heat exchanger module according to the invention obtained by welding-diffusion bonding of grooved and stacked plates, before the step of opening the channels; FIG. 4A is a cross-sectional and longitudinal sectional view of the stack of the elementary module according to FIG. 4; - Figures 5, 6 and 7 are perspective views of three elementary exchanger modules obtained according to the invention, before their mutual assembly to form a monobloc exchanger according to the invention; FIG. 8 is a perspective view of an example of a monobloc exchanger according to the invention obtained by edge-to-edge positioning and then welding-diffusion joining of the three elementary modules according to FIGS. 5 to 7; FIG. 8A is a cross-sectional view of the module according to FIG. 8, showing the holes made during the machining of the plates of the elementary modules and some of which allow the connection of the different zones of the elementary modules positioned edge-to-edge and others allow the vacuuming of the interfaces to be welded between elementary modules positioned edge-to-edge.
    The terms "longitudinal" and "lateral" are to be considered in relation to the geometrical shape of the metal plates which determine the geometrical shape of the stacks of the heat exchanger module according to the invention. Thus, in the end the four longitudinal sides of the stack of an elementary exchanger module according to the invention are those which extend parallel to the longitudinal axis X of the plates, that is to say along their length . The two lateral sides of the stack are those which extend along the lateral Y axis of the plates, orthogonal to the X axis, that is to say according to their width.
    The terms "above" and "below" are to be considered with respect to the direction of the stack of the exchanger module. Thus, the top plate, which forms all or part of an anvil, is the last plate that is stacked on others.
    Step a /:
    First of all, a number of several exchanger elementary modules, which may be of different sizes, are produced in the same way.
    The embodiment according to the first step a / of an elementary module 1.1 is described, based on metal plates 10, for example type 316L stainless steel, of length 11 and width 12 (FIG. 3A). The banks and anvils of the plates 10 are advantageously dimensioned in such a way that during an assembly by diffusion welding in CIC the deformations are controlled.
    Step i /: In order to produce an element of a first fluid circuit C1, one of the main faces 101 of a metal plate 10 is machined with grooves 20 that are straight and parallel to the length 11 of the plate in the example illustrated (Figure 3B).
    Step ii /: In order to produce an element of a second fluid circuit C2, the main faces 102 of a metal plate 10 are machined in the other, 30 grooves that are straight and parallel to the width of the plate in the illustrated example (Figure 3C).
    The grooves 20, 30 can be made by any suitable means: mechanical machining, chemical etching, stamping ...
    As usual, then, additional parts are produced which are necessary for producing the stack of grooved plates 10 and for assembling them (tools). This may include alignment rods, holding tools (uniaxial diffusion welding), possibly a container if the stack of plates is assembled by diffusion welding by CIC.
    Stages il / et il /: cleaning is carried out using solvents and detergents, plates 10.
    Step iii /: After having cleaned them, all the plates 10 are stacked so as to reconstitute both the channel elements 2 of the first circuit C1 and the channel elements 3 of the second circuit C2.
    During stacking, all the plates 1 are aligned relative to each other by means of alignment pins or not shown centering pins, inserted into blind holes.
    FIGS. 4 and 4A show an example of a stack for the production of an elementary exchanger module 1.1 with a superposition of the channels 2, 3 of the two fluid circuits C1, C2.
    Step iv /: The periphery of the complete stack (block) is sealed and each interface is degassed by an opening opening which is obstructed. To achieve the tightness at the periphery of the stack, complete stacking is carried out in a container.
    The container, made of stainless steel sheet folded and welded by TIG process, is itself cleaned and its cover. The lid is TIG welded to the container and the container is evacuated by pumping through a tube welded to one of its sides. The tube is then pinched, cut and itself welded to prevent an introduction of air into the container.
    The container, and thus the complete stack, is then subjected to a low pressure CIC cycle comprising heating from 900 to 1100 ° C. for a period of 1 to 4 hours under a pressure of 30 to 300 bar, then cooling in several hours and a depressurization.
    All of these steps i / iv / are carried out for each of the elementary modules 1.1, 1.2, 1.3 intended to constitute the monobloc exchanger according to the invention.
    Step b /: For each of the elementary modules 1.1, 1.2, 1.3, their reduction is then realized including a reduction of the banks by milling and the opening of the channels 2 and / or 3 by cutting the ends of the stack which close them.
    In the illustrated example: the elementary module 1.1 has been machined so as to have a length 14 and a width 13, with all the channels 2, 3 of both the first circuit and the second circuit that have been opened, that is to say, all leading out (Figure 5); the elementary module 1.2 has been machined so as to have a length 14 and a width 15, with all the channels 2 of the first circuit, parallel to the length of the exchanger, which have been opened at their two ends, while the Channels 3 of the second circuit parallel to the width of the exchanger were opened on only one of their end (Figure 6); the elementary module 1.3 has been machined so as to have a length 14 and a width 16, with all the channels 2 of the first circuit parallel to the length of the exchanger which have been opened at their two ends, whereas the channels 3 of the second circuit, parallel to the width of the exchanger, were opened on only one of their end (Figure 7).
    Step c /: At the end of the machining of all the elementary modules, they are positioned edge-to-edge. In the illustrated example, the three elementary modules 1.1, 1.2, 1.3 of the same length 14 but of different width 13, 15, 16 are joined by their longitudinal edge on the side so as to constitute a block 1 of external dimensions 14 × ( 13 + 15 + 16) (Figure 8).
    Step d /: once the edge-to-edge positioning of the elementary modules 1.1, 1.2, 1.3 achieved, then the assembly of the interfaces of the exchanger constituted. This is advantageously implemented by means of diffusion welding by CIC. The reduced elementary modules are first cleaned with solvents and detergents.
    Then, the interfaces are sealed by TIG welding and then the sealed interfaces are placed under vacuum between the elementary modules and thus also those of the channels that communicate with them, in order to ensure their continuity from an elementary module to a single module. other.
    FIG. 8A thus shows the machining operations 31 (bores) previously made and which make it possible to connect the various zones of channels 3 to be welded together as well as the machining operations 32 which make it possible to weld a pipe and thus to perform the evacuation.
    The valves are then sealed.
    Finally, block 1 of elementary modules 1.1, 1.2, 1.3, obtained a CIC low-pressure cycle, typically at a pressure between 20 and 500 bar, preferably between 30 and 300 bar. The choice of the pressure results from a compromise between quality of welding to obtain and acceptable deformation of the unopened channels.
    One or more machining operations can be carried out later to finalize the monoblock heat exchanger 1, in particular to open the closed fluid circuit.
    The exchanger can then be subjected to a high-pressure CIC cycle, typically at a pressure of between 200 and 2000 bar, preferably between 500 and 1200 bar. During this cycle, we perfect the assembly of the constituent plates of the elementary modules and that of the modules together.
    It is also possible to report by welding unrepresented fluid distribution manifolds, so as to supply and / or recover a fluid in each of the first C1 and second C2 circuits at the ends of the grooves forming the channels 2, 3.
    By means of the process according to steps a / d, a compact, large-sized, and / or a large number of channels whose geometrical shape has undergone very little deformations compared to the initial one conferred during the stacking.
    Of course, the present invention is not limited to the variants and described embodiments provided by way of illustrative and non-limiting examples.
    In the illustrated example, the elementary exchanger modules are laterally contiguous. One can also consider to position them edge-to-edge in the direction of the height, that is to say stack them on each other. In this case, the two fluid circuits can be opened during assembly of the exchanger: the applied CIC cycle can then be a high pressure type cycle as above. Positioning can also be done in the lengthwise direction, that is, end-to-end, following each other, or in several directions at the same time.
    In the example illustrated, all the constituent plates of all the elementary modules are made of the same material, preferably a type 316L stainless steel. It is also conceivable to have plates of different constituent material within the same elementary module or plates of different material from one elementary module to another.
    In the illustrated example, it is expected to achieve the seals at the interfaces between the elementary modules by welding. Any other means for achieving the seal and maintaining its integrity during the passage welding diffusion block can be implemented.
    The size of the channels for each of the fluid circuits may be different depending on the nature and properties of the fluids to be conveyed, the allowable pressure drops and the desired flow rate. Several elements of the same circuit can be stacked in order to optimize a functionality of the exchanger, for example the heat exchange or the flow rate of one of the fluids.
    If the illustrated example relates to exchangers with exactly two fluid circuits, it is quite possible to manufacture an exchanger with three or more fluid circuits, from two, three or more elementary exchanger modules.
    The two fluid collectors can be arranged on either side of the exchanger, or alternatively on the same side of the exchanger.
    The heat exchangers obtained according to the method of the invention can be assembled to each other, for example by using flanges or by welding the fluid supply pipes. It is thus possible to envisage making a heat exchanger system with several heat exchangers interconnected in which the exchanges are made in several stages with different average temperatures or temperature differences per module sufficiently reduced to reduce the thermal stresses in the materials. For example, in the case of a heat exchanger in which it is desired to transfer the heat from a first fluid to a second fluid, it is possible to design an exchanger system in which each exchanger makes it possible to reduce the temperature of the first fluid. a given value, thus limiting the constraints with respect to the case of a single heat exchanger design with a higher temperature difference. For this, the inlet temperature of the second fluid may differ from one module to another. In another example, a reactor-exchanger system makes it possible to carry out a complex chemical reaction by stages by precisely controlling the reaction temperature at each stage, for optimum control of the chemical reaction, minimization of risks and maximization of yields.
    A heat exchanger system with several heat exchangers also makes it possible to reduce maintenance costs by allowing the individual replacement of a faulty exchanger, or even the manufacturing costs by standardization of the exchangers.
    权利要求:
    Claims (17)
    [1" id="c-fr-0001]
    A method of producing a heat exchanger (1) with at least two fluid circuits each comprising channels, comprising the following steps: a / providing at least two elementary heat exchanger modules (1.1, 1.2, 1.3) ...), the realization of each elementary module comprising the following steps: i / realization of one or more elements of one of the two fluid circuits, said first circuit, each element of the first circuit comprising at least one metal plate ( 10) having first grooves (20) forming at least a portion of the channels (2) of the first circuit; ii / producing one or more elements (1) of at least one other fluid circuit, said second circuit, each element of the second circuit comprising at least one metal plate (10) comprising second grooves (30) forming at least a part of the channels (3) of the second circuit; iii / stacking the metal plates (10) of the elements of the first and second circuits so as to form their channels (2, 3); iv / soldering-diffusion joint between the element or elements of the first circuit and the element or elements of the second circuit, stacked on one another; b / modification of at least one of the elementary modules comprising a reduction of the width of at least one of the banks and / or the thickness of at least one of the anvils of at least one of the modules and optionally an opening of the channels (2, 3) of the first circuit and / or the second circuit to the outside; c / edge-to-edge positioning of the elementary modules (1.1, 1.2, 1.3 ...) of which at least one reduces, according to one of their longitudinal edges or one of their lateral edges; d / assembly of the interfaces between the edge-to-edge elementary modules, in order to obtain the exchanger in one-piece form.
    [2" id="c-fr-0002]
    2. Method according to claim 1, wherein before step iii / stacking, it carries out a step il / and iii / cleaning the plates of each element respectively of the first circuit and second circuit.
    [3" id="c-fr-0003]
    3. Method according to claim 1 or 2, wherein step iv / is carried out by applying a relatively low pressure isostatic compression (CIC) cycle to the sealed and degassed stack of each elementary module.
    [4" id="c-fr-0004]
    4. The method of claim 3, the CIC cycle according to step iv / being carried out at a pressure between 20 and 500 bar, preferably between 30 and 300 bar.
    [5" id="c-fr-0005]
    5. Method according to any one of claims 3 or 4, the CIC cycle according to step iv / being carried out at a temperature between room temperature and 1100 ° C, preferably between 900 and 1100 ° C.
    [6" id="c-fr-0006]
    6. Method according to one of the preceding claims, wherein, in step b /, the reduction of the width of at least one of the banks and / or the thickness of at least one of the anvils of at least one of the modules is made by removing the tools by demolding or machining, or by machining a portion of the non-grooved edges of the plates and / or anvils.
    [7" id="c-fr-0007]
    7. Method according to any one of the preceding claims, wherein during step b /, the opening of the channels can be performed by machining the ends of the module or drilling against the channels.
    [8" id="c-fr-0008]
    8. Method according to any one of the preceding claims, wherein step c / edge-to-edge positioning consists of a stack of the elementary modules by the main faces of the end plates of the modules.
    [9" id="c-fr-0009]
    The method of any one of claims 1 to 7, wherein step c / edge-to-edge positioning consists of edge-to-edge alignment along the length of the elementary modules.
    [10" id="c-fr-0010]
    The method according to any one of claims 1 to 7, wherein step c / edge-to-edge positioning consists of a lateral edge positioning of one of the elementary modules against a lateral edge of the other modules. elementary.
    [11" id="c-fr-0011]
    11. The method as claimed in claim 1, wherein step d is performed by electron beam welding, brazing or soldering-diffusion of the reduced modules between them.
    [12" id="c-fr-0012]
    12. The method of claim 11, the step d / consisting of diffusion welding with application of at least one isostatic hot pressing (CIC) cycle.
    [13" id="c-fr-0013]
    13. The method of claim 12, the welding-diffusion of the reduced elementary modules according to step d / is carried out during the high pressure cycle for finishing the welding of the internal interfaces of the elementary modules, step b / including an opening of the channels (2, 3) of the first circuit and / or the second circuit to the outside.
    [14" id="c-fr-0014]
    14. Method according to any one of the preceding claims, an elementary module comprising plates of different materials.
    [15" id="c-fr-0015]
    15. Method according to any one of the preceding claims, the constituent material or materials of an elementary module being different from that or those of another elementary module.
    [16" id="c-fr-0016]
    16. A method according to any one of the preceding claims, comprising a step e / final machining to finalize the monobloc exchanger.
    [17" id="c-fr-0017]
    17. Heat exchanger with at least two fluid circuits obtained according to the method according to any one of the preceding claims.
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    同族专利:
    公开号 | 公开日
    EP3178598A1|2017-06-14|
    EP3178598B1|2019-04-24|
    US20170157723A1|2017-06-08|
    FR3044752B1|2017-12-29|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    FR2998953A1|2012-11-30|2014-06-06|Jean-Claude Geay|Modular plate heat exchanger for use in ventilation system, has heat exchanger modules arranged in direction such that first circulation spacer unit of each module is in watertight communication with first circulation space|
    FR3005499A1|2013-05-10|2014-11-14|Commissariat Energie Atomique|METHOD OF MAKING A HEAT EXCHANGER MODULE HAVING AT LEAST TWO FLUID CIRCULATION CIRCUITS.|CN107825076A|2017-11-13|2018-03-23|贵州航帆精密机械制造有限公司|A kind of processing method of major diameter thin plate disk|
    US10766097B2|2017-04-13|2020-09-08|Raytheon Company|Integration of ultrasonic additive manufactured thermal structures in brazements|
    US10898976B2|2017-11-06|2021-01-26|AXH Air-Coolers, LLC|Method of manufacturing a box header for heat exchanger|
    JP2019130586A|2018-02-02|2019-08-08|日鉄日新製鋼株式会社|Set of austenitic stainless steel sheet, manufacturing of conjugate, and conjugate|
    法律状态:
    2016-12-30| PLFP| Fee payment|Year of fee payment: 2 |
    2017-06-09| PLSC| Publication of the preliminary search report|Effective date: 20170609 |
    2017-12-29| PLFP| Fee payment|Year of fee payment: 3 |
    2019-12-31| PLFP| Fee payment|Year of fee payment: 5 |
    2021-09-10| ST| Notification of lapse|Effective date: 20210806 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1561906A|FR3044752B1|2015-12-07|2015-12-07|METHOD OF MAKING A HEAT EXCHANGER WITH AT LEAST TWO CIRCULATING CIRCUITS OF FLUID, LARGE NUMBER OF CHANNELS AND / OR LARGE DIMENSIONS|FR1561906A| FR3044752B1|2015-12-07|2015-12-07|METHOD OF MAKING A HEAT EXCHANGER WITH AT LEAST TWO CIRCULATING CIRCUITS OF FLUID, LARGE NUMBER OF CHANNELS AND / OR LARGE DIMENSIONS|
    EP16201988.9A| EP3178598B1|2015-12-07|2016-12-02|Method for producing a heat exchanger with at least two fluid flow paths, with a large number of channels and/or large dimensions|
    US15/370,448| US20170157723A1|2015-12-07|2016-12-06|Method for production of a heat exchanger with at least two fluid circulation circuits with a large number of channels and/or large dimensions|
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