EP0617249A2 - Heat exchanger - Google Patents

Abstract

A heat exchanger (2) comprises an end tank (6) which defines, in this apparatus, a fluid inlet (16) via which fluid enters the heat exchanger during operation, and a fluid outlet (20) via which fluid leaves the heat exchanger (2) during operation, a plurality of heat-exchanger tubes (8) having end portions (10) by which the heat-exchanger tubes are connected to the said end tank (6), a plurality of heat-exchanger fins (12) connected to the heat-exchanger tubes (8), a plurality of end adapters (28) provided on the said end tank (6), extending outwards therefrom and defining passages in the said end tank, the said end portions (10) of the heat-exchange tubes being dimensioned to receive the said end adapters (28), wherein the end adapters (28) are each provided with two annular grooves (29) spaced axially on their external surface, an O-ring seal (30) being placed in each annular groove (29) in order to make a leaktight joint between the heat-exchanger tubes (8) and the end adapters (28). <IMAGE>

Description

Field of the invention

The present invention relates to a heat exchanger of the fin tube type for use, in particular but not exclusively, as an evaporator in an automotive air conditioning system.

Prior art

Conventionally, a fin-tube type heat exchanger for use as an evaporator or condenser comprises a plurality of U-shaped heat exchanger tubes on which are arranged a large number of fine metal fins. The heat exchanger tubes are connected, via inlet and outlet manifolds comprising a plurality of tubular connections, to an inlet or outlet for coolant or are connected to U-bends, one or more passages flows for the coolant being defined between inlet and outlet.

Instead of providing separate manifolds and elbow connections, the heat exchanger tubes can be connected to a connection tank or to an end tank which is provided with an inlet and an outlet for connection to the cooling circuit, and which is internally divided so as to define with the heat exchanger tubes the passage or the circulatory passages of the fluid between a fluid inlet and outlet. The heat exchanger tubes are connected to the end tank by projecting tubular ends provided on the end tank and which are received in end portions of the heat exchanger tubes, an adhesive, or any other curable synthetic material. , being used to seal the connection. A heat exchanger of this type is known by British Patent No. 1601429. During the mounting of the recesses defined around the projecting tubular connections are provided with the hardenable material, recesses into which the ends of the heat exchanger tubes are inserted. Some clearance is provided between the protruding tubular connections and the heat exchanger tubes to allow the injection of curable material between the two.

It is also known to weld or braze the ends of the heat exchanger tubes to the projecting ends.

A disadvantage of a welded or brazed joint, or of a joint using an adhesive or curable material, is that such joints are liable to leak. Such seals can also be reduced internally or plugged when sealing material enters the tube. When using welding, there are obvious safety risks associated with this technique. The manufacture of these seals is also relatively expensive.

Summary of the present invention

The object of the present invention is to provide a heat exchanger whose connections between the end tank and the heat exchanger tubes overcome the above-mentioned difficulties and can be formed easily and efficiently.

In accordance with the present invention, a heat exchanger is proposed comprising:
an end reservoir defining in this apparatus a fluid inlet through which, in operation, fluid enters the heat exchanger, and a fluid outlet through which, in operation, fluid exits from the heat exchanger;
a plurality of heat exchanger tubes having end portions through which the heat exchanger tubes are connected to said tank end;
a plurality of heat exchanger fins connected to the heat exchanger tubes;
a plurality of nozzles provided on said end tank defining passages in said end tank, said tips receiving or being received by end portions of respective heat exchanger tubes, to form the connection between said tank end and said heat exchanger tubes;
wherein O-rings are provided between said end portions of the heat exchanger tubes and said end pieces to provide a seal between the two, and wherein annular grooves are formed in said end portions of the exchanger tubes or in said ends, grooves in which said O-rings are placed.

The above arrangement provides a particularly effective fluid tight connection between the end tank and the heat exchanger tubes, and which is free of solder or adhesive. Another advantage is that the seals can be separated to allow internal cleaning, then reassembled. During assembly, the O-rings are compressed to ensure an effective fluid-tight seal.

In a preferred embodiment, the tips protrude outward from the end reservoir, and are formed with said annular grooves on the outside. The end portions of the heat exchanger tubes are preferably flared to receive the end pieces.

The tips can, as a variant, protrude towards the inside of the end reservoir, the annular grooves being formed inside the tips.

Preferably, said end pieces or end portions heat exchanger tubes which are received in said end portions of the heat exchanger tubes or end fittings are provided with two axially spaced annular grooves in which the respective O-rings are placed, thereby increasing the effectiveness of the seal .

The end tank may be a plastic end tank having molded aluminum tips and then fitted thereon.

In the absence of solder or other curable material, it is desirable to provide some other form of attachment of the heat exchanger tubes to the end tank to prevent detachment. When an end plate is provided to support the heat exchanger tubes away from the end tank, a housing can be provided to slide the assembly consisting of the end tank, heat exchanger tubes, fins and end plate. The housing may include a frame type housing having a base and opposite end faces which engage the end reservoir and the end plate respectively.

Alternatively, one or more fixing belts can be provided, extending around the assembly as a whole.

In a further variant, the end plate can be arranged so as to support the heat exchanger tubes near the end tank, the connection between the end plate and the end tank being formed by crimping.

Brief description of the drawings

• la figure 1 est une vue éclatée partiellement schématique d'un échangeur de chaleur selon l'invention;
• la figure 2 est une vue éclatée d'une forme de réalisation d'un échangeur de chaleur selon l'invention;
• la figure 3 est une vue en bout du réservoir d'extrémité tel qu'illustré à la figure 2;
• la figure 4 est une vue en bout dans le sens de la flèche A de la figure 3, dans laquelle on peut voir la construction interne du réservoir d'extrémité;
• les figures 5(a) et 5(b) sont des vues en section transversale partielle détaillées de la connexion d'un tube échangeur de chaleur au réservoir d'extrémité avant et après le montage;
• les figures 6(a) et 6(b) illustrent un ensemble évaporateur ayant un logement pour recevoir l'échangeur de chaleur, avant et après l'insertion de l'échangeur de chaleur;
• la figure 7 est une vue en section transversale détaillée d'une variante de connexion d'un tube au réservoir d'extrémité;
• les figures 8(a) et (b) sont des vues éclatées et à l'état monté d'une autre forme de réalisation de l'invention, illustrant une variante de connexion d'un réservoir d'extrémité au montage-bloc à serpentin; et
• les figures 9(a) et (b) sont des vues éclatées et à l'état monté d'une autre forme de réalisation de l'invention représentant encore une autre variante de connexion.

Embodiments of the invention will be described, by way of example only, with reference to the accompanying drawings, in which:

• Figure 1 is a partially schematic exploded view of a heat exchanger according to the invention;
• Figure 2 is an exploded view of an embodiment of a heat exchanger according to the invention;
• Figure 3 is an end view of the end tank as shown in Figure 2;
• Figure 4 is an end view in the direction of arrow A in Figure 3, in which one can see the internal construction of the end tank;
• Figures 5 (a) and 5 (b) are detailed partial cross-sectional views of the connection of a heat exchanger tube to the end tank before and after mounting;
• Figures 6 (a) and 6 (b) illustrate an evaporator assembly having a housing for receiving the heat exchanger, before and after insertion of the heat exchanger;
• Figure 7 is a detailed cross-sectional view of an alternative connection of a tube to the end tank;
• Figures 8 (a) and (b) are exploded views and in the assembled state of another embodiment of the invention, illustrating a variant connection of an end tank to the coil block assembly ; and
• Figures 9 (a) and (b) are exploded views and in the assembled state of another embodiment of the invention showing yet another connection variant.

Description of the preferred embodiment

Referring to the drawings, Figure 1 illustrates a view simplified exploded view of a heat exchanger according to the present invention.

The heat exchanger 2 essentially comprises a coil block assembly 4 connected to an end reservoir 6. The coil block assembly 4 comprises a plurality of heat exchanger tubes 8, each in the form of a hairpin, the ends 10 of which are visible in FIG. 1, and one of which is illustrated in the state withdrawn in FIG. 1.

A plurality of aluminum heat exchanger fins 12, of conventional shape, are connected to the heat exchanger tubes 8. Various connection methods can be used, but the heat exchanger tubes are preferably aluminum tubes which are widened by expansion through openings in the fins, to form a hard friction fit in the openings in the fins. An end plate 14, preferably also made of aluminum, is provided on the side of the coil block assembly 4 opposite the end tank 6, in order to support the heat exchanger tubes 8.

The end tank 6 is an injection molded plastic tank having a tubular fluid inlet 16 and a fluid outlet 18. In operation, the end tank 6 is connected by an expansion valve 22 to a fluid circuit cooling. The end tank 6 comprises a plurality of internal partitions 24 defining therein a plurality of compartments 26, as can be seen in FIGS. 3 and 4. Passages leading into the compartments 26 of the end tank are defined by openings 27 in one face of the end tank which is provided with tubular end pieces 28 projecting towards the outside. The end pieces 28 are preferably formed of short tubular sections of aluminum or copper, which are machined then molded and attached to the end tank 6, although the end pieces 28 may be made of plastic, individually molded with the end tank 6.

The end reservoir 6 is preferably formed according to a "lost core" method, in which a polymer is injected into a mold which has been previously charged with an injection molded core, of low melting metal, which is subsequently melted to give the hollow end tank. This method is particularly suitable for obtaining the relatively complex shape of the interior of the tank.

The heat exchanger tubes 8 are provided with flared or "bell-shaped" end portions 10, dimensioned to receive the end pieces 28, as can best be seen in FIG. 5. The end pieces 28 are each formed with a pair of annular grooves 29 axially spaced on their external surface, grooves in which the respective O-rings 30 are placed. The connection between the heat exchanger tubes 8 and the respective end pieces 28 is a greasy fit, the O-rings being compressed in the grooves 29, to thereby form an effective fluid tight seal.

As a variant of the arrangement described above, it will be noted that these end pieces 28 could equally well be dimensioned to receive the end portions 10 of the heat exchanger tubes 8. In a further variant, the end pieces could be designed so as to extend towards the inside of the end tank, the end portions of the heat exchanger tubes being dimensioned to be received in the end pieces, as illustrated in FIG. 7. In this figure, an end portion 10 ′ a heat exchanger tube 8 'is received in the end piece 28' projecting inwards. Instead of forming the grooves on the end caps, these could be formed on the end portions of the heat exchanger tubes inside these where they receive the tips, or outside when these are received by the tips.

Additional fixing of the end tank 6 to the coil block assembly 4 is obtained by providing a cassette-type housing system in which the heat exchanger in the assembled state can be received by sliding, so as to provide a support in the axial direction of the heat exchanger tubes 8 and the end pieces 28 to maintain the connection. As shown in FIG. 6, the housing comprises a sliding support 32 of frame type comprising a base 34 and end portions' 36, 38 which come into engagement with the end reservoir 6 and the end plate 14 for prevent the heat exchanger tubes 8 from detaching from the end reservoir 6, and an opening 40 through which the heat exchanger is introduced into the support 32. A cover plate 42 of the housing is provided to close the opening 40, and has a tongue 44 for engaging with a groove 46 provided in the support 32. FIG. 6 also illustrates the support as positioned between a housing 48 for a conventional air blower and a housing 50 for supplying air.

As a variant of this housing, as seen in FIGS. 8 (a) and (b), circumferential tension belts 48, for example made of steel or nylon, can be fixed around the heat exchanger in order to ensure the axial support. The belts 48 are fixed on the end tank at the fixing points 50, and extend around the fins / heat exchanger tubes and the end plate 14 ', while being placed in slots 52 in flanged backs end of the end plate 14 '.

As an additional variant, as seen in FIGS. 9 (a) and (b), an end plate 52 is provided at near the end tank 6, provided with a crenellated edge. The end tank 6 is in this case provided with a raised flange 54 molded in the end tank, the end tank 6 and the heat exchanger assembly being fixed to each other by crimping, as this can best be seen in detail in Figure 9 (b).

The heat exchanger just described has the advantages that avoiding welding, or using an adhesive or other curable material results in a more efficient fluid tight connection, in which problems of leakage are reduced and problems of internal obstruction of the passages are avoided. The fact that there is no additional sealing material also facilitates the automation of the mounting process. The connections can also be separated, the end tank 6 being removed from the heat exchanger tubes 8, in order to allow internal cleaning of the tubes and of the tank, while allowing subsequent reassembly.

The use of a plastic end tank 6 makes it possible to provide an end tank of narrower section than the conventional arrangement present using a mounting of manifolds and U-bends, allowing better use of space. occupied by the heat exchanger to provide heat exchange surfaces, thereby increasing the efficiency of the heat exchanger.

Conventionally, the heat exchanger is placed in the air duct between the air blower housing and the air supply housing by engagement with positioning tabs in the duct. The use of a cassette type housing facilitates the insertion of the heat exchanger, and furthermore eliminates the need to have a sealing material around the heat exchanger, which is generally used to ensure that the entire air flow passes through the heat exchanger.

Claims (13)

Heat exchanger comprising:
an end reservoir defining in this apparatus a fluid inlet through which, in operation, fluid enters the heat exchanger, and a fluid outlet through which, in operation, fluid exits from the heat exchanger;
a plurality of heat exchanger tubes having end portions through which the heat exchanger tubes are connected to said end tank;
a plurality of heat exchanger fins connected to the heat exchanger tubes;
a plurality of nozzles provided on said end tank defining passages in said end tank, said tips receiving or being received by end portions of respective heat exchanger tubes, to form the connection between said tank end and said heat exchanger tubes;
wherein O-rings are provided between said end portions of the heat exchanger tubes and said end pieces to provide a seal between the two, and wherein annular grooves are formed in said end portions of the exchanger tubes heat or nozzles, grooves in which are placed said O-rings. Heat exchanger according to claim 1, in which the annular grooves are provided on the end pieces. A heat exchanger according to claim 1, wherein the end pieces project outwardly from the end reservoir, and are formed with said annular grooves on the outside. Heat exchanger according to claim 3, in which the end portions of the heat exchanger tubes are flared end portions of the tube which receive the end pieces. A heat exchanger according to claim 1, wherein the end pieces project towards the inside of the end tank, said annular grooves being formed inside the end pieces. Heat exchanger according to claim 1, in which each said end piece or end portion of the heat exchanger tubes connected thereto is provided with two axially spaced annular grooves in which the respective O-rings are placed. Heat exchanger according to claim 1, in which the end tank is a plastic end tank in which aluminum end caps are molded and then added. Heat exchanger according to claim 1, in combination with a housing in which the heat exchanger can be slidably received, said housing serving to prevent the heat exchanger tubes from detaching from the end tank. A heat exchanger according to claim 8, wherein an end plate is provided to support the heat exchanger tubes in an area remote from the end tank, and wherein said housing is a frame type housing comprising a base and Opposite end faces which engage the end tank and the end plate respectively. The heat exchanger of claim 1, further comprising one or more securing straps extending around the end tank and heat exchanger tubes to prevent the tubes from detaching from the end tank. A heat exchanger according to claim 1, wherein an end plate is provided to support the heat exchanger tubes in an area near the end tank, and wherein said end plate is connected to said end tank by crimping, which prevents the heat exchanger tubes from detaching from the tank end. Heat exchanger comprising:
an end reservoir defining in this apparatus a fluid inlet through which, in operation, fluid enters the heat exchanger, and a fluid outlet through which, in operation, fluid exits from the heat exchanger;
a plurality of heat exchanger tubes having end portions through which the heat exchanger tubes are connected to said end tank;
a plurality of heat exchanger fins connected to the heat exchanger tubes;
a plurality of nozzles provided on said end tank extending outward therefrom and defining passages in said end tank, said end portions of the heat exchanger tubes being sized to receive said tips ;
wherein said end pieces are each provided with two annular grooves spaced axially on their outer surface, and wherein an O-ring seal is placed in each annular groove to provide a tight seal between the heat exchanger tubes and the end pieces. Heat exchanger assembly comprising:
an end reservoir defining in this apparatus a fluid inlet through which, in operation, fluid enters the heat exchanger, and a fluid outlet through which, in operation, fluid exits from the heat exchanger;
a plurality of heat exchanger tubes having end portions through which the heat exchanger tubes are connected to said end tank;
a plurality of heat exchanger fins connected to the heat exchanger tubes;
an end plate disposed at a distance from said end tank to support the exchanger tubes heat;
a plurality of nozzles provided on said end tank extending outward therefrom and defining passages in said end tank, said end portions of the heat exchanger tubes being sized to receive said tips ;
a frame type housing comprising a base and opposite end faces inside of which the end tank, the heat exchanger tubes, the heat exchanger fins and the end plate can be received by sliding, said opposite end faces engaging the end tank and the end plate respectively to prevent the heat exchanger tubes from detaching from said end pieces;
wherein said end pieces are each provided with two annular grooves spaced axially on their outer surface, and wherein an O-ring seal is placed in each annular groove to provide a tight seal between the heat exchanger tubes and the end pieces.

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