DE102006054814B4 - Soldered flat tube for capacitors and / or evaporators - Google Patents

Abstract

Soldered flat tube for capacitors and / or evaporator in air conditioning systems, especially in motor vehicles, which is produced by forming endless aluminum-containing metal strip, two narrow sides (1) and two broad sides (2) and inner channels (K) has a hydraulic diameter (h _D ), which is equal to or greater than 0.254 mm, and a pipe wall thickness (W _d ) of less than 0.25 mm, characterized in that both narrow sides (1) are reinforced by at least twice the thickness (S _d ) of the remaining pipe wall thickness (W _d ), wherein the flat tube consists of three metal strips (a, b, c), wherein two metal strips (a, b) form the pipe wall and the third metal strip (c) an inner insert (IE ),
wherein the two sheet metal strips (a, b) which form the tube wall are formed identically, wherein one longitudinal edge of the sheet metal strip has a larger arc and the other longitudinal edge of the sheet metal strip is formed with a smaller arc,
wherein the metal strips (a, b) in such a way ...

Description

The The invention relates to a soldered Flat tube for Capacitors and / or for Evaporator in air conditioning systems, especially in motor vehicles, which by Forming of one or more endless aluminum sheet metal strips produced is, has two narrow sides and two broad sides and inner channels owns, which have a hydraulic diameter, the same or greater than 0.254 mm, and has a tube wall thickness of less than 0.25 mm.

Soldered flat tubes for capacitors are from the EP 0 237 164 A1 known. Flat tubes whose hydraulic diameter of the inner channels has a value in the range of 0.381-1.778 mm, have now become fully established for so-called parallel current capacitors. In the local 1 For example, such a parallel-current capacitor is shown and, moreover, a manufacturing method for such capacitors is proposed. To produce the flat tubes, a sheet metal strip is formed into a flat tube and welded with a longitudinal seam. A second sheet metal strip is formed with corrugations running in the transverse direction and inserted into the flat tube. The wave crests and the wave troughs are soldered to the broad sides of the flat tube so that longitudinal inner channels are formed which have hydraulic diameters which have a value in the mentioned size range. (look there 2 )

In many other cases be flat tubes for Capacitors and / or for Evaporator manufactured by extrusion, the realization especially small hydraulic diameter, combined with essential smaller pipe wall thicknesses and channel wall thicknesses manufacturing technology Limits are set. Also from the point of view of costs, the extrusion process can not always withstand comparison with other procedures. This applies at least when the flat tubes have dimensions (D; d), as for Capacitors / evaporator needed become. Furthermore, in the case of flat tubes for condensers and / or for evaporators the compared to other heat exchangers in motor vehicles much higher Internal pressure taken into account become what led to that has that in practice so far the pipe wall thickness of such flat tubes at best between about 0.25 mm and 0.30 mm. The hydraulic Diameters are present Flat tubes for capacitors and / or evaporators available on the market in the range of about 1.10-1.60 mm or slightly about that.

There are also several earlier patent applications of the Applicant. One of them has the file number DE 10 2006 006 670.7 receive. It proposes flat tubes with extremely small wall thicknesses for cooling liquid coolers and for intercoolers (s. 6 and 8th - 10 ).

The introductory preamble corresponds to the EP 1 681 528 A1 , In this publication flat tubes for capacitors are specifically addressed. It is quite progressive, because it also refers to very thin-walled flat tubes. The metal strip forming the channels should have a thickness of less than 0.1 mm. From the applicant's point of view, however, the flat tubes disclosed there have a decisive disadvantage with all advantages, which consists in the fact that the stability of the flat tubes is not sufficient.

From the JP 57-105 690 A , A flat tube is known, which can be produced from three metal strips. This flat tube has two differently shaped metal strips to form the pipe wall, which is in need of improvement from a manufacturing point of view.

The US Pat. No. 5,185,925 Although has the formation of the pipe wall two identically shaped metal strips, but there was the tube wall itself substantially reshaped, which also means from a production point of view, additional effort.

The The object of the invention is to provide lightweight and about as powerful and cost-effective producible capacitors and / or evaporators or of flat tubes therefor, the one improved stability should have.

These The object is achieved by the characterizing features of claim 1, which in conjunction with the Characteristics can be seen in the generic term.

It it is provided that both narrow sides of the flat tube are reinforced, by there should be a thickness which is greater than the pipe wall thickness, for example should there be at least twice the pipe wall thickness. The production of the heat exchanger network from such flat tubes and corrugated fins is by this proposal simplified, because its composition has become easier. In flat tubes of the prior art, the only one increased Have narrow side, care must be taken that all Flat tubes with the reinforced Narrow side pointing in one direction - mostly forward to the cooling air flow arranged become. This attention has become superfluous as proposed by both Strengthened narrow sides are.

It is further provided that the flat tube consists of three metal strips, with two metal strips forming the pipe wall and the third Sheet metal strip represents an indoor use.

In Further development of this idea is provided that the two metal strips, which form the pipe wall are formed identically by the one longitudinal edge the sheet metal strip a larger arc owns and the other longitudinal edge the sheet metal strip is formed with a smaller borrowing, wherein the Sheet metal strips are arranged so reversed to each other, that in each case the larger sheet one sheet metal strip the smaller sheet of the other sheet metal strip embraces.

A further reinforcement the two narrow sides is achieved by the inner insert two having deformed longitudinal edges, the inside of the narrow sides abut.

Regarding the Channel wall thickness is provided that this approximately between 0.03-0.10 mm or something more settled. For flat tubes from a single Sheet metal strips have the pipe wall thickness and the channel wall thickness the same measure. In terms of the pipe wall thickness is provided that this in the range of about 0.08 mm-0.20 mm, wherein the channel wall thickness is located between 0.03-0.10 mm. The is the case with two- or three-piece flat tubes.

Regarding the Flat tube dimension is provided that the small dimension (d) of the flat tube about 0.8-1.3 mm and the tall Dimension (D) is approximately between 8 and 20 mm, preferably approximately 12-16 mm.

Regarding the hydraulic diameter of the channels was found to be a value between 0.30 and 0.70 mm is particularly suitable, wherein an area between 0.40 and 0.60 mm offers special performance advantages emphasizes it.

Of the Condenser or evaporator as part of an air conditioner Motor vehicles, the one soldered heat exchanger networks from flat tubes and interposed ribs, through the cooling air flows, is characterized in that the flat tubes at least the features of Claim 1 have.

The accompanying drawings show predominantly multiple magnifications of different flat tube cross sections, which are beneficial for capacitors of air conditioners.

The 1 shows a made of three metal strips flat tube.

The 2 shows another but also made of three metal strips flat tube.

The 3 . 4 . 5 and 7a - 7d show further modified flat tubes made of three metal strips.

The 6 . 8th and 9 show different flat tubes, which consist of a single formed sheet metal strip. The 10 shows a producible from two metal strips flat tube. The 6 and 8th - 10 do not belong to the present invention.

All flat tubes have the common features, according to which the hydraulic diameter h _{D of} the channels K is greater than 0.254 mm, the tube wall thickness W _{d is} less than 0.25 mm and then both narrow sides 1 are reinforced by having a greater wall thickness S _d than the remaining pipe wall thickness W _d .

The channel wall thickness K _d may have a value which is between 0.03 and 0.15 mm.

The in the 1 - 3 such as 5 and 7 shown flat tubes consist of three metal strips a, b, c and represent the presently preferred embodiments, wherein the flat tubes from the 7 represents the currently most preferred variant. The flat tubes in the mentioned figures are in agreement that the two sheet-metal strips forming the wall parts a and b are identical and arranged laterally reversed to each other. The one longitudinal edge of the metal strips a and b was formed with a larger arc and the other longitudinal edge was provided with a smaller arc. Due to the inverted arrangement of the larger arc of a metal strip surrounds a smaller arc on the other metal strip b to the one narrow side 1 to form the flat tube and the larger arc on the other metal strip b engages the smaller arc on a metal strip a around the other narrow side 1 to form the flat tube. Furthermore, the flat tubes of the mentioned figures agree that the third metal strip c represents an inner insert whose two longitudinal edges are inside in the narrow sides 1 and reinforce them further. It is spoken here of sheet metal strips a, b, c, because the flat tubes of endless metal strips or sheet metal strips are produced on a roller mill and then cut to the required length, which was not shown here. The 1 is different from the 2 through the formation of the inner insert c. In the 2 the possibility is shown that the wave geometry or the design of the chambers K can be designed differently in order to correspond to specific thermodynamic conditions or to achieve related advantages. It was also in the left narrow side 1 of the flat tube 2 indicated that the inner insert c can still be folded at the longitudinal edge, for additional reinforcements of the narrow sides 1 to reach. Although this possibility has been shown only at the one longitudinal edge, it can be seen that both longitudinal edges of the inner insert c can be configured in this way. That in the 3 and 4 embodiment shown is particularly suitable for inner inserts c which are made of extremely thin metal strips. Here can be thought of sheet thickness of 0.03 mm or a little more. The sheet thickness of the wall parts a and b is very low, about 0.10 mm. Here too the narrow sides 1 To be able to strengthen sufficiently, the longitudinal edges of the inner insert c were folded several times horizontally and inside in the narrow sides 1 created. The horizontal folds of the longitudinal edges of the inner insert c cause here the thickness S _{d of} the narrow sides 1 even the multiple of the thickness W _{d of} the rest of the tube wall is - to 5-8 times or a little more could be quite advantageous.

The two under the 5 illustrated flat tubes are distinguished by the geometry of their chambers K and in that the measure already indicated, the two longitudinal edges of the inner insert c to fold was carried out in the lower illustration, but not in the upper.

The four representations under the 7 differ first by the choice of the thickness of the metal strips a, b and c and then by the hydraulic diameter h _{D of} the channels K. The hydraulic diameters in the upper illustration are smaller and are approximately at 0.5 mm. In addition, the edge design of the inner insert c was slightly modified. The lowest values are in the embodiment according to the 7d in front. The hydraulic diameter h _D is there for example about 0.455 mm, the pipe wall thickness W _d is about 0.115 mm and the channel wall thickness K _d is about 0.05 mm. The hydraulic diameter h _D is known to result from h _D = 4 × A / U, where A is the cross-sectional area of the channel K and U represents the humidified circumference of the channel K.

The 6 shows suitable existing from a single sheet metal versions of a soldered flat tube. Accordingly, the flat tube has no separate indoor use. Rather, the chambers were K by one in a broadside 2 trained folding 10 generated, located on the other broadside 2 supported. The narrow sides 1 were each generated from numerous horizontal folds F, which, as the figures show, a thickness of the narrow side 1 Provide that is several times the thickness of the metal strip.

The 8th shows another flat tube of a single sheet metal strip in an intermediate stage, shortly before completion. This flat tube should consist of a metal strip whose thickness W _{d is} closer to the upper limit, so could be about 0.20 mm. The reason for this could be seen in that the thickness S _d in the narrow sides 1 only twice the thickness of the metal strip or the pipe wall thickness W _d .

In contrast, the shows 9 that it is possible, even with flat tubes made of a sheet metal strip very stable narrow sides 1 train. For this purpose, a sheet metal strip of thickness approximately between 0.10-0.15 mm can be selected. To produce this flat tube, two spaced folds F are generated in the sheet metal strip. In each case, a bend B is generated in the folds F, as a result of which the narrow sides 1 of the flat tube are shown. Before that, however, one strip section of the sheet-metal strip must be corrugated, whereby the channels K are formed in the closed flat tube, as shown in the figure.

Finally, the shows 10 a flat tube with channels K, which has been produced from two metal strips a, c. The metal strip a provides the pipe wall and the metal strip c, however, an indoor use. The metal strip a may here have a thickness which is approximately at 0.20 mm. The inner liner c has only a thickness of about 0.15 mm or less, for example, 0.10 mm. First, a fold F is formed in the metal strip a. At the one longitudinal edge of the metal strip a, a small arc is formed in this embodiment. The other longitudinal edge of the metal strip a can also be preformed so that it can be placed around the small bow later. The metal strip c, the inner insert of the flat tube, is provided with a wave formation and with two formed longitudinal edges. Then, the inner insert c is inserted into the gradually to be closed flat tube. In the course of the closure of the flat tube, a bend B is produced in the aforementioned fold F, as a result of which the narrow side shown in the figure above 1 is trained. In the closed flat tube, the two longitudinal edges of the inner insert c lie inside in the narrow sides 1 of the flat tube. Some steps of the described production process were in the 10 shown.

Claims (6)

Soldered flat tube for capacitors and / or evaporator in air conditioning systems, especially in motor vehicles, which can be produced by forming endless aluminum-containing metal strip, two narrow sides ( 1 ) as well as two broadsides ( 2 ) and having inner channels (K) having a hydraulic diameter (h _D ) equal to or greater than 0.254 mm, and a tube wall thickness (W _d ) of less than 0.25 mm, characterized in that both narrow sides ( 1 ) are reinforced in that they have at least twice the thickness (S _d ) of the remaining pipe wall thickness (W _d ), wherein the flat tube consists of three metal strips (a, b, c), wherein two metal strips (a, b) form the tube wall and the third sheet metal strip (c) is an inner insert (IE), wherein the two metal strips (a, b), which form the tube wall, are formed identically, wherein the one longitudinal edge of the sheet metal strip has a larger arc and the other longitudinal edge of the metal strip with a smaller arc is formed, wherein the sheet metal strips (a, b) are arranged to each other, that in each case the larger arc of a sheet metal strip engages around the smaller arc of the other sheet metal strip and that the inner insert (IE) has two deformed longitudinal edges, the inside of the Narrow sides ( 1 ) issue. Brazed flat tube according to claim 1, characterized in that the channel wall thickness (K _d ) is located approximately between 0.03-0.15 mm. Brazed flat tube according to claim 1, characterized in that the tube wall thickness (W _d ) is in the range of about 0.08 mm-0.20 mm. soldered Flat tube according to claim 1, characterized in that the small Dimension (d) of the flat tube is about 0.8-1.3 mm and the big dimension (D) is between about 8 and 20 mm, preferably about 12-16 mm. Brazed flat tube according to claim 1, characterized in that the hydraulic diameter (h _D ) has a value which is between 0.30 and 0.70 mm. Condenser or evaporator as part of a Airconditioning of motor vehicles, a dissolved heat exchanger network of flat tubes and intervening ribs through which cooling air flows therethrough in that the flat tubes are designed according to at least one of the preceding claims are.