The invention relates to a heat exchanger with at least one header tube for the reception of flat tube ends, according to the preamble of patent claim 1, known from the applicant's DE-A-198 46 267. The invention relates, furthermore, to a method for the production of a heat exchanger, according to the preamble of patent claim 7.
The heat exchanger which has become known from the applicant's DE-A-198 46 267 has a header tube with a slot which runs in the longitudinal direction and which receives flat tube ends rotated through 90 degrees with respect to the flat tubes. In this case, the flat tube ends are arranged in mutual abutment, that is to say one behind the other without a gap in the longitudinal slot, and are soldered in a fluidtight manner to the header tube. Owing to this arrangement, the tube division, that is to say the distance between the flat tubes of this heat exchanger which are arranged parallel to one another is restricted, specifically to the depth of the flat tubes (extent in the air flow direction). As a result, the height of the ribs which are arranged between the flat tubes is also fixed. This means a restriction in the design of flat tube heat exchangers of this type which are intended particularly for CO2 air-conditioning systems for motor vehicles. The header tube for the known heat exchanger is produced either by cutting machining, for example by the milling of the longitudinal slot into a thick-walled tube, or by the bending round of a plane sheet metal strip. Since, in cutting machining, there is always the risk that chips remain on the workpiece and therefore subsequently infiltrate as impurities into the coolant circuit, noncutting manufacture is to be preferred. Since the pressures in CO2 air-conditioning systems are considerably higher than in conventional air-conditioning systems having the coolant R134a, the wall thickness of a header tube is relatively large, which does not make it any easier to machine or form the latter.
The object of the present invention is to improve a heat exchanger with a header tube of the type initially mentioned, to the effect that the header tube can be produced in a simple way, as far as possible leaves behind no impurities after the production process and is not subject to the restrictions mentioned in terms of the tube division. The object of the invention is also to describe an economical method for the production of the heat exchanger initially mentioned, in particular of its header tube.
The solution for achieving this object arises from the features of patent claims 1 and 8. The dependent claims relate to advantageous refinements and developments of the invention. According to the invention, the header tube has a continuous longitudinal seam or longitudinal slot which runs in the longitudinal direction and into which reception orifices for the flat tube ends are integrally formed at predetermined intervals. The header tube is therefore designed as an open hollow profile which is slotted in the longitudinal direction in which the edges of the longitudinal slot partially bear directly against one another and are soldered in this region and partially are deformed according to the contour of flat tube ends so as to form reception orifices. This affords the advantage that the tube division selected may be even greater than the depth of the flat tube, this being advantageous particularly in the dimensioning of gas coolers or condensers for a CO2 air-conditioning system.
According to an advantageous development, the reception orifices for the tube ends are produced by noncutting deformation, that is to say plastic deformation, thus entailing the advantage that no chips which would contaminate the coolant circuit are left behind. Moreover, this noncutting forming incurs lower costs.
According to an advantageous development of the invention, the edges of the slotted hollow profile are prolonged so as to form set-out edge strips, thus giving the header tube a higher strength, since the edge strips act in the manner of a reinforcing bead. If the edge strips are set out in a V-shaped manner, this results in an assembly-friendly introduction slope for the flat tube ends to be inserted. The edge strips may also be set out or angled in such a way that they lie in a common plane and thus form with the cross section of the header tube an omega shape. This increases the strength even more than a V-shaped set-out of the edge strips. In addition, when twisted flat tubes are used, the set-out edge strips constitute a limitation of the depth of insertion of the flat tubes.
By the method according to the invention, it is possible to produce the reception orifice for the flat tube ends by plastic deformation, using a simple wedge-shaped tool. First, a hollow profile slotted in the longitudinal direction is produced by bending round, so that the edges touch one another along a contact line in the region of the longitudinal slot and edge strips are set out in a V-shaped manner so as to form an introduction slope. This V-shaped set-out results in an advantageous introduction slope for the wedge-shaped tool which has the contour of the flat tube ends. With the hollow profile being supported at the same time by a die, this tool is driven into the longitudinal slot, the result of which is that the material of the hollow profile is displaced in the region of the wedge-shaped tool, that is to say the material flows into the adjacent regions. Since the wall thickness of the header tube is relatively large, there is sufficient thickness so that no material weakening occurs, on the contrary the opposite being achieved due to strain hardening. If the tool is appropriately fitted with a plurality of stamps (wedge-shaped tools), all the orifices can be produced in one operation or in steps in order to keep the degrees of deformation per operation lower. This also results in a higher surface quality of the reception orifices for the flat tube ends.
After the reception orifices are ready-calibrated, the flat tube ends are introduced, the edge strips set out in a V-like manner acting as an assembly-friendly introduction slope. The header tube is subsequently soldered to the inserted flat tube ends, the entire longitudinal slot of the hollow profile being soldered in a leaktight manner, this soldering taking place, together with the soldering of the entire heat exchanger including ribs, in a soldering furnace. So that sufficient solder flows into the solder gaps when the soldering temperature is reached, the hollow profile and/or the flat tube ends are solder-plated at least on one side, so that there is sufficient solder available for leaktight soldering. When extruded flat tubes which, as a rule, have no solder layer are used, there is sufficient solder available for leaktight soldering if, in particular, the hollow profile is solder-plated on the inside.
An exemplary embodiment of the invention is illustrated in the drawing and is described in more detail below. In the drawing:
It would also be possible, as is not illustrated here, to have a two-stage or multistage method for shaping the reception orifices 5, that is to say by means of a two-stage or multistage tool.
Number | Date | Country | Kind |
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102 21 457.3 | May 2002 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP03/04762 | 5/7/2003 | WO |