ITBO20120131A1 - HEAT EXCHANGER PARTICULARLY SUITABLE FOR USE AS AN EVAPORATOR - Google Patents

Description

DESCRIPTION of the industrial invention entitled: â € œHeat exchanger particularly suitable for use as an evaporatorâ €

The present invention relates to a heat exchanger particularly suitable for use as an evaporator. The invention has been developed with particular regard, although not limited to, a heat exchanger suitable for use both as an evaporator and as a condenser, for use in sectors such as the air conditioning of motor vehicles, or in pumps. of heat, without however excluding other uses in which an economical, efficient and reliable evaporator is desirable.

The heat exchanger of the present invention makes use of the so-called tubes with minichannels, also called â € œmultipoleâ € tubes, which are flattened tubes within which thin parallel channels are obtained in which the exchange fluid, generally water or steam, flows parallel. The heat exchange takes place between the exchange fluid that flows in the tubes with mini-channels and the air that laps the outside of these tubes. To increase the surface lapped by the air and improve the heat exchange efficiency, as is known, metal fins are arranged between adjacent pipes in thermal contact with the pipes themselves. An example of a heat exchanger of this type is described in document EP 0 654645.

The use of heat exchangers of the type with mini-channels as condensers in air conditioning systems is quite widespread, as this technology allows to combine high energy efficiency with low costs, at least for mass production.

In the case of evaporators, on the other hand, the problems to be faced are more complex and, for the moment, have substantially prevented the spread on the market of mini-channel air evaporators.

As is known, in evaporators the exchange fluid that flows inside the tubes passes from a liquid phase to a vapor phase, absorbing heat from the external environment, ie cooling the air that laps the tubes and the heat exchange fins. The absorption of heat from the external environment leads to the generation of condensate which, in conditions of temperatures close to or below zero, can lead to the formation of ice or frost on the tubes and fins of the evaporator, with consequent reduction of the exchange properties and loss of efficiency. The frequency of defrosts is particularly high for coils with mini-channels, as they have a high density of fins with small air passages: this can result in severe energy penalties, so an effective solution to this problem is a fundamental point for to ensure greater diffusion on the market for this technology. The penalty due to frost is essentially linked to the poor distribution of the fluid, since the production of frost is concentrated in the flooded areas of the evaporator, leaving dry areas where the heat exchange is not very intense clean.

Another problem of the heat exchangers used as evaporators is linked to the distribution of the exchange fluid. In fact, unlike what happens in condensers, it is a two-phase fluid (liquid-vapor) whose distribution risks occurring in a non-uniform way of exchange inside the tubes. An uneven distribution of the exchange fluid leads to the formation of areas with greater condensation on the outside of the pipes, with the damaging consequences indicated above.

Although various solutions are known to solve the problems mentioned above, the need has always been felt to increase the efficiency and reduce the costs of evaporators. Hence an object of the present invention, which consists in the provision of a heat exchanger which can be used in particular as an evaporator and which is particularly effective in preventing the formation of frost or ice on its outside, preventing the stagnation of condensation on the pipes and the heat exchange fins. Another object of the invention is to realize a heat exchanger to be used in particular as an evaporator, in which the flow of exchange fluid in the gas or vapor phase is as uniformly distributed inside the tubes, in particular in the tubes. with mini-channels. Another object of the invention is that of realizing a heat exchanger of the type indicated above which is simple and economical to manufacture, and which is reliable in use in particular as an evaporator.

In order to achieve the objects indicated above, the invention relates to a heat exchanger having the characteristics indicated in the following claims.

A particular advantage of a heat exchanger according to the present invention is that it can be used in a reversible machine, ie operating for example as a water cooler in the summer season and as a heat pump in the winter. The mini-channel heat exchanger of the present invention would therefore act as a condenser, appointed to rejection the heat to the external air, in the operating mode as a cooler, and as an evaporator, with the function of drawing the thermal energy from the low temperature, in the mode of operation as a heat pump.

Further characteristics and advantages of the invention will become evident from the following detailed description of a preferred but non-limiting example of implementation, with reference to the attached figures, given by way of non-limiting example, in which:

- Figure 1 is a front elevation view of a heat exchanger suitable for use as an evaporator of the present invention, with a plurality of vertical pipes between which fins are arranged which, for clarity of illustration, have been shown only in the part on the right in the figure;

- figure 2 is a perspective view, partial and on an enlarged scale, of a portion of the heat exchanger of figure 1;

- figure 3 is a section on an enlarged scale of a detail of the lateral extremity portion of the heat exchanger of figure 1, along the line Î ™ Î -Î ™ Î ™ Î ™ of figure 1;

- figure 4 is a partial schematic cross section, on an enlarged scale, along the line IV-IV of figure 1;

Figure 5 is a schematic perspective view of the heat exchanger of Figure 1 including the feed and collection manifolds of the exchange fluid;

- figure 6 is a section on an enlarged scale of a detail of a duct for introducing the exchange fluid into the heat exchanger of figure 5, and

- figure 7 is a variant of the detail referred to in figure 6.

With reference now to the figures, a heat exchanger intended in particular for use as an evaporator is indicated as a whole with the reference number 1. The heat exchanger 1 comprises a plurality of pipes 2 arranged side by side and parallel in a vertical direction. The pipes 2 are of the type with mini-channels and, as better visible in fig. 2 or in the section of fig. 3, have a substantially flattened shape and comprise inside them a plurality of parallel and side-by-side channels 3, intended to be crossed by an exchange fluid of the heat exchanger. The tubes 2 lead at their ends respectively into a supply manifold 4, preferably cylindrical, to which the exchange fluid is fed, and into a collection manifold 5, also preferably cylindrical, in which the exchange fluid is collected afterwards. having passed through the pipes 2. In the particular case of use of the heat exchanger as an evaporator, the exchange fluid is fed to the supply manifold 4 in the liquid phase, and reaches the collection manifold 5 in a gas or vapor phase at low pressure. The supply manifold 4 has a plurality of inlet ports 6 (eight in number, in the particular but not limiting example of the figures). The collection manifold has one or more outlet openings 7 (two in number, in the particular but not limiting example of the figures).

Between adjacent pipes 2 metal fins 8 are inserted which are in thermal communication with the pipes 2, that is, they are placed side by side and preferably welded to them, and which increase the heat exchange surface with the air passing through the heat exchanger. The fins 8 are made starting from a metal strip which is repeatedly bent to S on itself, as clearly visible in the detail of figure 2. A particular expedient of the present heat exchanger is to realize the bending loops 10 of the metal strip which forms the fins 8 with a gentle curvature and a relatively large radius. In this way, the risk of condensation forming in the loops 10 is reduced when the heat exchanger is used as an evaporator, where the air, passing between the fins 8, cools.

As can be seen in Figure 4, the fins 8 are of the type that includes â € œlouverâ € 9, that is, louvered openings. The particular arrangement of the heat exchanger, with the pipes 2 vertically and the `` louvers '' 9 of the fins 8 that open substantially one above the other in a vertical direction, allows an optimal disposal of the condensate that can form on the pipes 2 and on the fins 8 when used as an evaporator. Unlike most evaporators, in fact, in which the tubes for the exchange fluid are arranged horizontally, in the present heat exchanger the tubes 2 do not hinder the dripping of condensate, but rather help it. The â € œlouverâ € 9 openings allow the condensate to pass through all the fins 8. These measures significantly favor the disposal of the condensate which otherwise could freeze or frost on the pipes 2 and / or on the fins 8, considerably reducing efficiency of the heat exchanger in its use as an evaporator.

Another device that contributes overall to the disposal of the condensate that can form outside the heat exchanger 1 is clearly visible in figures 3, 4 and 5 and consists of the protrusion of the pipes 2 with respect to the fins 8, in the direction of the flow. of air indicated by arrows A and on the side of the heat exchanger opposite to that which is hit by the air during use. In practice, the width of the metal strip forming the fins 8 is less than the width of the tubes 2. In this way, while on the side of the front face la of the heat exchanger 1, which in use is hit by the air A, the front edges 8a of the fins 8 are substantially aligned with the front edge 2a of the tubes 2, on the other side of the rear face 1b of the heat exchanger 1 the rear edges 8b of the fins 8 end before the rear edge 2b of each tube 2, leaving free a continuous vertical zone 2c of each pipe 2. The continuous vertical zone 2c constitutes a sort of drain guide for the condensate that forms in the rear part 2b of the heat exchanger used as evaporator.

The sides of the exchanger 1 are preferably closed by sections 12 (see Figure 3) preferably fixed to the exchanger 1 by means of rivets, screws or the like, or also by welding and other known connection means.

With reference now to figure 5, it can be seen how the exchange fluid is fed to the various inlet ports 6 of the supply manifold 4 in parallel, through ducts 13 of small cross-section which exit from a flow distributor 14 of a generally known type, which homogenizes the fluid and gaseous phases of the exchange fluid entering the heat exchanger 1. The various ducts 13 which branch off from the flow distributor 14 are inserted in the supply manifold 4, whose internal tubular cavity is substantially cylindrical and it does not have any internal separation partition, in points equally spaced along its length. The horizontal arrangement of the manifold facilitates a uniform distribution of the flow rate, greatly limiting the stratification effects of the exchange fluid due to gravity.

In the upper part of the heat exchanger 1, the collection manifold 5 is also preferably tubular in shape, with a substantially cylindrical internal cavity and without internal septa. The outlet openings 7 for the exchange fluid, suitably spaced apart, lead into one or more corresponding outlet ducts 11.

Figure 6 illustrates a detail of the conformation of an inlet 6 for the connection of the ducts 13 to the supply manifold 4, in order to distribute the exchange fluid as uniformly as possible inside the mini-channels 3 of the pipes 2 which are engage on the supply manifold 4. The inlet port 6 comprises an inlet portion 16 of larger diameter, from which a tubular section 15 of a smaller diameter extends in a substantially horizontal direction, with a longitudinal axis X-X, which passes through an opening 17, obtained on the wall of the supply manifold 4, orthogonally to the vertical development of the tubes 2 according to the Y-Y direction. Inside the supply manifold 4, the terminal end 18 of the tubular section 15 is curved downwards so as to open towards the bottom part of the supply manifold 4, with axis oriented in the Y-Y direction but facing from the opposite side to the inlet of the mini-channels of the pipes 2. This conformation of the inlet ports 6 to the supply manifold 4 responds to the need to avoid stratification of the exchange fluid and to promote high turbulence to homogenize the two-phase outflow. In practice, the flow of exchange fluid entering the supply manifold 4 is directed orthogonally to the plane tangent to the lowest generatrix of the circular section of the supply manifold 4, with the outlet of the terminal end 18 positioned near the point lower than the supply manifold 4 in order to dissolve any liquid layer collected on its bottom.

Figure 7 shows a variant of the inlet port 6a for the supply manifold 4, which is simpler to manufacture and assemble. In this case, the inlet 6a comprises a substantially rectilinear tubular body 20 which crosses the wall of the supply manifold 4 in the horizontal direction X-X. At the end of the tubular body 20 outside the supply manifold 4 there is an inlet 21 for one of the exchange fluid supply ducts 13. Inside the supply manifold 4, at the end of the tubular body 20, there is a tangential hole 22 with a substantially vertical axis, directed according to the Y-Y direction of development of the mini-channels of the tube 2, but facing away from the tube 2, towards the bottom of the supply manifold 4, to achieve the same purposes and functions mentioned above with reference to the variant of figure 6. The substantially rectilinear conformation, preferably slightly tapered of the tubular body 20, allows easy assembly of the same inside the power supply manifold 4.

According to a particularly advantageous feature of the present invention, the external surface of the heat exchanger 1, and in particular at least the tubes 2 and the fins 8, is subjected to a series of surface treatments intended to increase its hydrophilicity, so that the condensate that forms there can drain more easily downwards, and thus make the solutions of particular conformation of the heat exchanger described above effective.

According to a preferred embodiment, the heat exchanger 1 is made of aluminum and the joints between the various constituent elements are obtained by brazing. In a first phase of surface treatment, the heat exchanger is degreased with an alkaline substance in order to remove the contaminants present on its surface. After the degreasing phase, a washing is carried out, followed by a neutralization with nitric acid to remove the surface layer of Al (OH) 3 and create the conditions for better adhesion on the surface of the subsequent products. This is followed by a phase of further washing and subsequent blowing, again for the purpose of cleaning and preparing the external surfaces of the heat exchanger. Thereafter, a titanation is carried out, i.e. a chemical conversion obtained by means of titanium in which a layer of titanium phosphate is formed on the surface of the heat exchanger. The titanium phosphate layer has anticorrosive and adhesive properties useful for anchoring, as will be said, a subsequent polymeric layer. This operation is preferably followed by a further washing and subsequent blowing. The actual hydrophilic coating is then created by immersion in a bath preferably composed of some products in emulsion:

- a polymer, preferably based on nylon or the like, which makes the surface of the heat exchanger hydrophilic, - chromium (Cr3), to increase resistance to corrosion, and - optionally, an antibacterial product.

The total thickness of the hydrophilic coating is preferably about 0.1 mm. A further blowing preferably follows, before the exchanger is subjected to a final firing phase, preferably at a temperature from about 120 ° C to about 160 ° C to complete the preferred surface treatment of the present invention.

In the use of the heat exchanger of the present invention, in particular for exclusive use as an evaporator or with the possibility of alternating condenser / evaporator operation in a reversible type machine, assembly takes place substantially with the orientation of figure 1, i.e. say with the supply manifold 4 and collection manifold 5 arranged horizontally, with the supply manifold 4 at the bottom and the collection manifold 5 at the top. Preferably, the tubes 2 are oriented vertically, even if their possible inclination which is not excessive along a horizontal axis, substantially parallel to the axis of the supply manifolds 4 and collection 5, cannot be excluded.

In operation as an evaporator, the exchange fluid arrives in the mixed phase, comprising the two liquid and gaseous phases, to the flow distributor 14 which, in a known way, provides for homogenizing the two phases and sending them into the ducts 13 which feed the supply manifold 4 through the inlet ports 6, 6a, whose particular shape - together with the absence of separating baffles inside the manifold 4 - allows to obtain an optimal and uniform distribution of the exchange fluid entering the heat exchanger 1. The fluid flows up the mini-channels 3 of the tubes 2 warming up gradually and passing completely to the low pressure gas or steam phase in the collection manifold 5. The heat necessary for the evaporation of the exchange fluid is removed from the air that hits the exchanger heat 1 in the direction of the arrows A (figs. 2, 3 and 4) and which, in contact with the external surface of the pipes 2 and the fins 8, cools. The cooling of the air that strikes the heat exchanger 2 can generate condensate which percolates, thanks to the combined action of the hydrophilic surface of the heat exchanger 1, of the vertical arrangement of the pipes 2 which do not hinder the flow of condensate water towards the low, as well as by the presence of the â € œlouverâ € 9 on the fins 8 and by the zone 2c on the pipes without fins which acts as a guide for the condensate.

The low pressure gas or steam which collects in the upper collection manifold 5 is then sent, through one or more ducts 11, to the rest of the circuit of the known thermal machine.

Naturally, the principle of the invention remaining the same, the embodiments and details of realization of the present invention may vary widely, without thereby departing from the scope of the present invention.

Claims (10)

CLAIMS 1. Heat exchanger particularly suitable for use as an evaporator comprising: - an array of parallel flattened pipes (2), provided inside with parallel mini-channels (3) intended to be crossed by an exchange fluid; - a tubular supply manifold (4) in communication with the first ends of all the tubes (2), intended to be fed by the exchange fluid to start it along the tubes (2) of the heat exchanger (1); - a tubular collection manifold (5) in communication with the second ends of all the tubes (2), within which the exchange fluid is collected after having passed through the tubes (2) of the heat exchanger (1); - a plurality of fins (8) interposed between pairs of adjacent tubes (2) and in thermal communication with them, intended to be lapped by air passing through the heat exchanger in a crossing direction (A) substantially orthogonal to the length of the pipes (2), from a front face of the exchanger (la) to a rear face (1b) of the exchanger; wherein the feed manifold (4) and the collection manifold (5) are arranged parallel, with their axes substantially horizontal, the feed manifold (4) being arranged below the collection manifold (5) so that the pipes (2) assume an almost vertical direction, the width of the fins (8) in the direction of passage (A) of the air being less than the width of the pipes (2), which have in correspondence of the rear face (lb) of the exchanger an area (2c) devoid of fins (8) oriented substantially vertically to favor the drainage of the condensate forming on the external surface of the pipes (2). 2. Heat exchanger according to claim 1, wherein the fins (8) are provided with louvered openings (9) arranged substantially aligned superimposed, to facilitate drainage to facilitate the drainage of the condensate forming on the external surface of the fins (8). 3. Heat exchanger according to claim 1 or 2, wherein the outer surface at least of the tubes (2) and of the fins (8) has a hydrophilic coating to favor the drainage of the condensate forming thereon. 4. Heat exchanger according to any one of the preceding claims, wherein the supply manifold (4) has a continuous substantially cylindrical internal tubular cavity, without separating baffles, into which a plurality of inlet openings (6, 6a) leads . 5. Heat exchanger according to claim 4, wherein the inlets (6, 6a) are arranged equidistant from each other. 6. Heat exchanger according to claim 4 or 5, wherein each inlet (6, 6a) has a tubular portion (15, 20) arranged inside the internal tubular cavity of the supply manifold (4) and provided with a opening (15, 22) directed towards the internal wall of the supply manifold (4) in the opposite direction with respect to the end of the pipes (2). 7. Thermal machine comprising at least one heat exchanger (1) according to any one of the preceding claims. 8. Thermal machine according to claim 7, the thermal machine being of the reversible type to operate according to two complementary thermal cycles, the at least one heat exchanger (1) acting respectively as a condenser and as an evaporator in both of said two complementary thermal cycles. 9. Process for manufacturing a heat exchanger according to any one of claims 1 to 6, comprising the steps of superficially treating at least the tubes (2) and the fins (8) of the exchanger to achieve a hydrophilic coating. 10. Process according to claim 9, wherein the heat exchanger is aluminum which is surface treated with at least one degreasing treatment, one neutralization treatment with nitric acid, one titanation treatment, and the application of a layer of a polymer, preferably based on nylon or the like, which makes the surface of the heat exchanger hydrophilic, combined in emulsion with chromium (Cr3), to increase resistance to corrosion.