FR2980840A1 - PLATE FOR HEAT EXCHANGER AND HEAT EXCHANGER WITH SUCH PLATES - Google Patents

Abstract

The invention relates to a plate (4, 12, 14) intended to allow a heat exchange between a first and a second fluid flowing in contact with the plate (4, 12, 14), said plate (4, 12, 14). being configured to define a circuit (8) comprising a plurality of successive passes (71, 72, 73, 74) in which the first fluid flows in a direction of flow by changing direction of flow from one pass to another, each of the passes (71, 72, 73, 74) having a passage section of the first fluid. According to the invention, the passage section of a pass (71, 72, 73, 74), said upstream, is larger than the passage section of another pass (71, 72, 73, 74), so-called downstream, located downstream of the upstream pass in the direction of flow of the first fluid in the circuit (8). The invention also relates to a heat exchanger provided with such plates.

Description

The invention relates to plates for heat exchangers and to plate heat exchangers, in particular for motor vehicles.

In this field, it is known exchangers, said charge air coolers, allowing a heat exchange between the charge air, for supplying the engine of the vehicle, and a coolant. They comprise a heat exchange bundle consisting of a stack of plates defining between them alternating circulation channels for the charge air and for the coolant. Stacked plate charge air coolers are known, as mentioned above, in which each plate guides the cooling liquid in a circuit forming several passes of identical section and inside which the coolant circulates according to a orthogonal direction to the supercharging air flow. Between each pass, the coolant changes direction of flow.

While traveling through the circuit, the temperature of the coolant increases, which causes a variation of its physical properties (in particular its density, its viscosity). However, when the physical properties of the coolant change, the pressure drop also changes.

In existing solutions, the widths of the passes are identical within the same circuit and does not adapt to the evolution of the pressure losses mentioned above, which has the effect of degrading the performance of the exchanger.

The pressure losses can indeed contribute positively to the heat efficiency of the exchanger because it is known that the greater the pressure loss, the more the flow flow can be turbulent mode, which is favorable to heat exchange, at least to a certain extent.

However, the pumps used for the circulation of the coolant have limited characteristics, in order to avoid too much penalizing the energy consumption taken from the engine of the vehicle.

It has thus been discovered in the context of the invention that a favorable relationship existed between the evolution of the size of passage passage sections and the evolution of the changes in the physical properties of the cooling fluid in order to reduce the loss of total load of the circuit without penalizing the thermal performance of the exchanger. The invention thus relates to a plate intended to allow a heat exchange between a first and a second fluid flowing in contact with the plate, said plate being configured to define a circuit comprising several successive passes in which the first fluid flows in one direction. flow by changing flow direction from one pass to another, each of the passes having a passage section of the first fluid. According to the invention, the passage section of a pass, called upstream, is larger than the passage section of another pass, called downstream, located downstream of the upstream pass in the direction of flow of the first fluid. in the circuit. Thus, by traversing the circuit, the first fluid circulates through passages whose passage section decreases which has the effect of accompanying the evolution of the pressure drops due to the increase in its temperature. The coefficient of pressure loss can then be kept relatively constant along the circuit. In the case of charge air coolers, the first fluid is a coolant and the second fluid is the charge air. According to one aspect of the invention, said plate comprises an initial pass and a final pass and the passage passage sections decrease from one pass to the other from the initial pass to the final pass. They decrease, for example, linearly or proportionally. According to another aspect of the invention, the passage section of the initial pass 5 is between 40 and 60% larger than the passage section of the final pass. According to a particular embodiment, said plate comprises four passes, said first pass, second pass, third pass and fourth pass, the first pass being connected to an input of the circuit, the second pass being connected to the first pass, the third pass pass being connected to the second pass and the fourth pass being connected on the one hand to the third pass and on the other hand to an output of the circuit. The passage section then decreases from the first pass until the fourth pass. Advantageously, the passage section of the first pass is between 5 and 15% larger than the passage section of the second pass. Advantageously, the passage section of the second pass is between 20 and 40% larger than the passage section of the third pass. In particular, the passage section of the third pass is between 5 and 15% larger than the passage section of the fourth pass. According to an exemplary embodiment, the distance between edges defining the first pass is between 30 and 35 mm, the distance between edges defining the second pass is between 27 and 32 mm, the distance between edges defining the third pass is between 22 and 25 mm and / or the distance between edges defining the fourth pass is between 20 and 23 mm. The borders defining a pass are, in particular, parallel to each other so that the passage section of a pass is constant. The passage section is measured in a plane perpendicular to an extension plane of the plate.

According to another aspect of the invention, the passes comprise disruptors of the fluid flow. The invention also relates to a heat exchanger, in particular intended for a motor vehicle, comprising plates as defined above, at least two of said plates being stacked one on the other in a pair of plates so that the circuit one of the two plates mirrors the circuit of the other of the two plates. It is understood here that two plates forming a pair of plates are stacked one on the other so that their circuit together form a circulation channel of the first fluid. Other features and advantages of the invention will become apparent on reading the following description of exemplary embodiments given by way of illustration with reference to the appended figures. In these figures: - Figure 1 is a perspective view exploding exploded heat exchanger according to the invention comprising four-pass plates; FIG. 2 is a top view of a plate comprising four passes, intended to identify the differences in passage sections of the different passes according to the invention. As illustrated in FIG. 1, the invention relates to a heat exchanger 1 allowing a heat exchange between a fluid to be cooled, in particular a gas G, and a coolant C. It could be a cooler of supercharging air in which a flow of compressed air for supplying a heat engine, for example a motor vehicle engine, is cooled by a coolant, including a mixture of water and glycol. The exchanger 1 comprises a heat exchange bundle 2 consisting of a stack of plates 4 between them determining alternating circuits 6, 8 for the fluid to be cooled and for the cooling liquid. The beam here is of generally parallelepipedal shape and has an exit face 10 and an opposite, non-visible inlet face of the fluid to be cooled. It is completed on both sides of the stack of a plate, said upper, 12 and a plate, said lower, 14. The heat exchanger 1 may also include a housing 5 in which the beam 2 is located . It guides the fluid to be cooled between the plates of the inlet face to the exit face 10 of the bundle 2. It consists here of two lateral walls 18, each coming against the edges 16, 16 'of the side plates 4, 12 14, of an upper wall 20, coming into contact with the upper plate 12 and a lower wall 22, coming into contact with the lower plate 14. The upper wall 20 may be provided with orifices 24, 26 allowing the passage, at the outlet and at the inlet, of the coolant C in the bundle 2. The exchanger 1 may also comprise nozzles 28, 30 for the outlet and / or inlet of the coolant communicating with said orifices 24, 26 provided in the case. The various components of the exchanger are, for example, aluminum or aluminum alloy. They are, in particular, soldered to each other.

Each plate 4, 12, 14 comprises, for example, a bottom 31, substantially plane, surrounded by a peripheral edge 32 terminated by a flat portion 34, for brazing the plates together. The coolant circuit 8 is defined, on the one hand, by said peripheral rim 32 and, on the other hand, by one or more edges 60, 60 ', for example made from material of the bottom 31 of the plate.

The plates 4, 12, 14 are grouped in pairs and assembled by their flats 34 and / or the edges 60, 60 '. In this way, the circuit of an upper plate 4 and a lower plate 4 of the same pair of plates complement each other to form a circulation channel for the coolant C. In other words, the plates 4 are stacked in pairs so that the coolant circuit C 8 of one of the two plates is vis-à-vis the coolant circuit 8 C of the other of the two plates of the same pair to form the circulation channel coolant C. The circuits 6 for the circulation of the fluid to be cooled are provided between two plates 4 vis-à-vis two pairs of adjacent plates 4. In the illustrated example, the top 12 and bottom 14 plates of the stack are assembled with the top and bottom walls 22 of the housing to define a coolant flow channel. The plates 4, 12, 14 have, for example, the general shape of an elongated rectangle having two long sides and two short sides, each plate having two bosses 38, a first of the bosses 38 having an inlet 42 of the circulation channel 8 coolant C and the other bosses 38 having an outlet 40 of the coolant flow channel C. The bosses 38 are located along the same small side of the plate 4, 12, 14. They are here pierced with a passage 50 of the coolant C and are intended to come into contact with the bosses 38 of an adjacent plate 4 to form respectively an inlet manifold 44, and an outlet manifold, not visible, for the coolant C. The inlet manifold 44 opens, for example, into the inlet pipe 30 through the inlet port 26 of the housing and / or the outlet manifold opens, for example, into the pipe output 28 through the port d e output 24 of the housing. In other words, the cooling fluid enters the beam through the inlet pipe 30 and is distributed between the plates 4 in the circuits 8 for circulating coolant through the inlet manifold 44. It flows into the circuits 8 flow of coolant C from their inputs 42 to their outputs 40 where it enters the outlet manifold. It then leaves the exchanger through the outlet pipe 30.

The bosses 38 of two pairs of plates 4 determine between them the height of the circulation circuits 6 for the fluid to be cooled.

An inlet manifold and an outlet manifold (not shown) may be adapted to the periphery of the housing to bring and evacuate the fluid to be cooled.

The exchanger may also comprise secondary exchange surfaces, for example corrugated disturbers reported between the plates 4 in the circulation circuits 6 of the fluid to be cooled G. These disrupters can disrupt the flow of the fluid to be cooled G to improve the heat exchange between the two fluids.

Each plate 4, 12, 14 for example comprises corrugations 52 arranged in the circuits 8 for circulating coolant C. These corrugations 52 extend between the pockets 38 constituting the inlet manifold and the outlet manifold 44 of the liquid C and the second longitudinal end of the plates 4, 12, 14. The corrugations 52 are, for example, derived from the bottom material 31 of the plates 4, 12, 14, in particular by stamping the plates 4, 12, 14. circuit 8 defined by the plates 4, 12, 14 to guide the coolant C in a number n of successive passes, here four, wherein the liquid flows between the inlet 42 and the output 40 of the circuit 8. Two passes adjacent are separated, for example, by the borders 32, 60, 60 'of the plates 4, 12, 14. The passes are arranged parallel to each other in an extension direction, here the long side of the plates. They may be provided in series one after the other. The edges 60, 60 'are thus oriented along the long side of the plates 4 to define a coil circulation of the coolant in each of the passes of each of the circuits 8 for circulating coolant C.

Some 60 of the borders extend from the edge 16 provided with the bosses 38 to the opposite edge 16 'while leaving a passage for the fluid to flow from the pass on one side of the edge 60 to the other. other pass. They alternate with borders 60 'extending from the edge 16' opposite to that 16 provided with the bosses 38 towards the edge 16 provided with the bosses 38 while leaving a passage for the fluid to flow from the pass lying d one side of the border 60 'to the other. In the example illustrated in Figures 1 and 2 where the plate is provided with four passes, there is a first pass 71, or initial pass 71, extending from the inlet 40 to the edge 16 'opposite the one 16 provided with bosses 38; a second pass 72 connected to the first and extending from the edge 16 'opposite the edge 16 provided with the bosses 38 to the edge 16 provided with the bosses 38; a third pass 73 connected to the second pass and extending from the edge 16 provided with the bosses 38 to the edge 16 'opposite that 16 provided with the bosses 38; and a fourth pass 74 connected on the one hand to the third pass 73 and on the other hand to the outlet 42 so that it extends from the edge 16 'opposite the edge 16 provided with the bosses 38 to the edge 16 equipped with bosses 38.

The circulation of the fluid to be cooled D in the circulation circuits 6 of the fluid to be cooled is thus effected in a direction generally perpendicular to that of the flow of the cooling liquid, the cooling liquid changing direction of flow of a pass to another.

A plate according to the invention is shown in Figure 2. Such a plate has a length L in the direction of extension of the passes and a width I in a direction D orthogonal to the direction of extension of the passes. In the exchanger, the direction D thus corresponds to the direction of flow of the fluid to be cooled. Similarly, in a plate comprising n passes, each pass has a width In corresponding to the distance along the direction D between two edges 32, 60, 60 'defining this pass. Thus, in the illustrated example, the first pass 71 has a width 11, the second passes 72 a width 12, the third passes a width 13 and the fourth passes 74 a width 14.

According to the invention, the passage section of a pass, called upstream, is larger than the passage section of another pass, called downstream, located downstream of the upstream pass in the direction of flow of the liquid of cooling in the circuit 8 for circulation of the coolant. The coolant flowing from the initial pass to the final pass, i.e., from the first pass 71 to the fourth pass 74, the passage section decreases from the first pass 71 to the fourth pass 74 There is thus an optimization of the loss of charge / thermal performance ratio. The section of passage of a pass is defined by its width multiplied by the height of the borders 32, 60, 60 'which define it. The borders 32, 60, 60 'being here substantially parallel to each other and of identical height, the comparison of the widths of passes is equivalent in the following description to a comparison of the passage sections of each pass. According to one aspect of the invention, the width li of the first pass 71 is between 5 and 15% larger than the width 12 of the second pass 72.

The width 12 of the second pass is here between 20 and 40% greater than the width 13 of the third pass 73. The width 13 of the third pass 73 is for example between 5 and 15% greater than the width 14 of the third pass 73. fourth pass 74. In an exemplary embodiment, the width of the initial pass, here the first pass 71, is between 40 and 60% greater than the width of the final pass, here the fourth pass 74.

In the example illustrated in Figure 2 the plate width I of the plate 4, 12, 14 is, in particular, equal to 120 mm and its length L is, for example, equal to 200 mm. In this case, the width li of the first pass 71 is in particular between 30 and 35 mm, the width 12 of the second pass 72 is, for example, between 27 and 32 mm, the width 13 of the third pass 73 is in particular between 22 and 25 mm and the width 14 of the fourth pass 74 is advantageously between 20 and 23 mm.

Claims (10)

REVENDICATIONS1. Plate (4, 12, 14) for enabling a heat exchange between a first and a second fluid (C, G) flowing in contact with the plate (4, 12, 14), said plate (4, 12, 14) being configured to define a circuit (8) comprising a plurality of successive passes (71, 72, 73, 74) in which the first fluid (C) flows in a direction of flow by changing direction of flow from a pass to the another, each of the passes (71, 72, 73, 74) having a passage section of the first fluid (C), characterized in that the passage section of a pass (71, 72, 73, 74), said upstream, is larger than the passage section of another pass (71, 72, 73, 74), called downstream, located downstream of the upstream pass in the direction of flow of the first fluid in the circuit (8 ). The plate (4, 12, 14) according to claim 1, said plate (4, 12, 14) comprising an initial pass (71) and a final pass (74), the pass passage sections (71, 72, 73, 74) decreases from one pass to another from the initial pass (71) to the final pass (74). 3. Plate (4, 12, 14) according to claim 2, wherein the passage section of the initial pass (71) is between 40 and 60% greater than the passage section of the final pass (74). 4. Plate (4, 12, 14) according to any one of the preceding claims, said plate (4, 12, 14) comprising four passes (71, 72, 73, 74), said first pass (71), second pass (72), third pass (73) and fourth pass (74), the first pass (71) being connected to an input (42) of the circuit (8), the second pass (72) being connected to the first pass (71). ), the third pass (73) being connected to the second pass (72) and the fourth pass (74) being connected on the one hand to the third pass (73) and on the other hand to an output of the circuit (40) . The plate (4, 12, 14) according to claim 4, wherein the passage section of the first pass (71) is between 5 and 15% larger than the passage section of the second pass (72). 6. Plate (4, 12, 14) according to any one of claims 4 or 5, wherein the passage section of the second pass (72) is between 20 and 40% greater than the passage section of the third pass (73). 7. Plate (4, 12, 14) according to any one of claims 4 to 6, wherein the passage section of the third pass (73) is between 5 and 15% greater than the passage section of the fourth pass (74). 8. Plate (4, 12, 14) according to one of claims 4 to 7, wherein the distance between edges (38, 60) defining the first pass (71) is between 30 and 35 mm, the distance between edges (60, 60 ') defining the second pass (72) is between 27 and 32 mm, the distance between edges (60', 60) defining the third pass (73) is between 22 and 25 mm and / or the distance between edges (60, 38) defining the fourth pass (74) is between 23 mm and 23 mm. The plate (4, 12, 14) according to any one of the preceding claims, wherein the passes (71, 72, 73, 74) comprise disrupters (52) of the fluid flow. 10. Heat exchanger (1), especially for a motor vehicle, comprising plates (4) according to any one of the preceding claims, at least two of said plates (4) being stacked one on the other in one pair of plates so that the circuit (8) of one of the two plates (4) is in mirror of the circuit (8) of the other of the two plates (4).