DE8612431U1 - Radiator pipe - Google Patents

Description

A^uminiümwerk ... GP 2994-DE

Description

The invention relates to extruded or extruded cooler tubes for countercurrent, cocurrent or cross-current coolers with continuous and half webs.

The well-known cooler pipes with continuous and half webs are used as heat exchangers in particular for oil and charge air coolers. These pipes belong to the class of technically smooth pipes in which the medium flows quickly; the corresponding heat exchange is too low for many types of application and therefore often has to be compensated for by dimensioning the cooler pipes unnecessarily large.

The advantage of the known cooler tubes is that they can be easily manufactured by extrusion or pultrusion, whereby they are preferably made of aluminum.

The aim of the present invention is to use simple means and to retain the advantageous manufacturing method of the known pipes to produce such cooler pipes that enable a significantly better heat exchange; the cooler pipes to be made available should have significantly better heat exchange properties with the same dimensions. -Ba

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The object of the invention is achieved in that the half-webs in the known cooler tubes are not straight but wave-shaped in the direction of flow. The cooler tubes according to the invention are defined in more detail in claims 1 to 4.

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The present invention provides access to cooler tubes with simple means that have significantly improved heat exchange compared to comparable previously known cooler tubes, because the measures according to the invention force a quasi-turbulent flow on the media flowing through the cooler tubes. This result is made possible with simple technical means, while at the same time continuous and economical mass production of the cooler tubes according to the invention is possible.

The invention is explained in more detail with reference to the following figures 1 to 5.

Fig. 1 is an oblique plan view of an embodiment of the cooler tube according to the invention in detail;
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Fig. 2 is a horizontal section through the cooler tube section according to Figure 1;

Fig. 3 is another embodiment of a cooler tube according to the invention in detail;

Fig. 4 are schematic representations of tools for
Radiator pipes.

^{and 5} tools for producing the inventive

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Figure i shows the extruded or extruded cooler tube 1. In the cooler tube there are alternating continuous webs 3 and half webs 4 next to each other.

On the surface 2 and, preferably, also on the opposite lower surface (not shown) nubs 5 are pressed in. These nubs 5 cause the surface 2 to curve inwards in the area of the flow channels for the medium between the continuous walls 3, so that the passage narrows; if this happens on the two opposite surfaces, considerable constrictions can occur with a corresponding nub depth, through which the quasi-laminar flow in smooth passages is changed into a quasi-turbulent flow.

Preferably, the studs 5 are attached to both sides of the connecting strip 6 of the cooler pipe surface 2 and half-webs 4 in such a way that the half-webs are deformed in a wave-like manner. This is also achieved by the studs, which are attached to the right and left along the imaginary strip 6, being offset from one another.

The resulting corrugation is defined in terms of its "wave length" by the longitudinal distance between the nubs offset from one another and in terms of its "amplitude" by the nub depth or the nub diameter. The optimal conditions in this regard can be selected by any person of average skill in the art through simple experiments after disclosure of the present inventive teaching, depending on the cooling tube material and the cooling tube dimensions.

Figure 2 shows a cross section through a particular embodiment of the cooling tube according to the invention according to

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Figure 1 again/ in this embodiment the

' Studs are arranged offset from one another along the imaginary strip 6 according to Figure 1. It should be noted here that the special case according to the invention is not shown in the figure, in which the studs 5 change the cross section of the flow channels between the continuous webs 3 in the stud area, without, however, causing the half webs 4 to corrugate. But even in this simplest embodiment according to the invention.

The embossed knobs create the quasi-laminar

Flow in the previously known comparable cooling pipes is considerably disturbed.

In the embodiment according to Figure 2, in which the reference symbols have the specified meaning, it is clear that the offset arrangement of the studs 5 causes the half-webs 4 to be bent in a wave-like manner. The additional deformation of the surface 2 in the stud area and possibly the opposite surface of the cooling tube is not taken into account in the drawing in this figure, but is nevertheless present.

Figure 3 shows another embodiment of the cooling pipes according to the invention. The cooling pipes of these systems require fins 7 attached to the upper side of the profile 2 for heat exchangers, which are constructed according to the co-current and countercurrent principle. With the exception of these fins 7, the cooling pipe 1 shown corresponds to the embodiments according to the invention according to Figures 1 and 2, whereby the reference symbols here also have the specified meaning.

In addition, the ribs 7 are also wave-shaped in such a way that the "wavelength" and "amplitude" are precisely defined and completely reproducible. This

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This is for the assembly of cooling systems, consisting
from the cooling tubes according to Figure 3 is an absolute requirement.
The manner in which this embodiment of the cooling tubes according to the invention can be produced is described below. ^--^

The production of the cooling tubes according to the invention according to Figures 1 and 2 is initially carried out in a manner known per se by extrusion or pultrusion of the
Profiles, for example made of aluminium. Immediately after

The nub roller 8 is mounted at the press outlet according to Figure 4f in such a way that it acts on the pressed profile to produce the nubs 5 in the cooling tubes according to the invention. This can also be done on both sides using two rollers 8, between which s

the profile goes through. ?

The knob roller 8 has knobs 9 which are on the
nub roller is arranged in mirror image to the nub pattern to be produced on the casing 2 of the cooling pipes according to the invention according to Figures 1 to 3, the exact j; positioning of the nubs, their height (or diameter) ' _fi and the distance "between the neighboring nubs I apply to the corresponding information that can be found in the descriptions of Figures 1 to 3. In corresponding \

The special embodiment of the cooling tubes according to the invention is produced in accordance with Figure 3 , whereby the corrugation of the fins 7 can be produced by the tool according to Figure 5, which additionally fulfills the function of the tool according to Figure 4. This
Tool is positioned and ^inserted in the same way.

, as was described for the mop roller according to Figure 4. This roller tool 10 also has a circumferential groove 11 which serves to receive and bend one of the ribs 7. When the .
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these enter the multi-directional grooves 11 and are bent in a wave-like manner; by selecting a corresponding circumference of the roller 10 and/or the number of curved arcs of the groove 11 on the circumference of the roller 10, the "wave length" of the wave support of the ribs 7 can be defined exactly and with great accuracy in a reproducible manner. Regarding the arrangement and mode of operation of the knobs 9, reference is made to the corresponding descriptions of Figure 4.

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Claims (5)

&bull; » 1 t ··■ &igr;"! '*! Ii ■■■&igr; la vt ■■ GP 2994-DE Aluminiumwerk Nenzing GmbH A-6710 Nenzing Claims 1. Extruded or extruded cooler tube for countercurrent, cocurrent and/or cross-current coolers with continuous and half webs with the formation of smooth channels between the continuous webs for the passage of a medium, characterized in that the cross section of the passage channels is changed by knobs (5) applied from the outside to the cooler tube casing (2). 5 ₍ Aluminium plant ... GP 2994-DE ■ · ■·· ·· ··· Il &igr; !■■■11 ■· ■» The The 2. Cooler pipe according to claim 1, characterized in that the half webs (4) are wave-shaped. 3. Cooler pipe according to claim 1 and/or 2, characterized in that, to the right and left of the connecting strip (6) of the cooler pipe casing (2) and the half-bridge (4), nubs (5) offset from one another and deforming the half-bridges (4) in a wave-like manner are pressed into the cooler pipe casing (2). 4. Cooler pipe according to claim 2, characterized in that additional ribs (7) arranged on the cooler pipe casing (2) and extending in the flow direction are of wave-shaped design. 5!l^&iJ<tool for producing a cooler tube (1) with wave-shaped rusted half-webs (4) and wave-shaped deformed longitudinal ribs on the outer shell (2) of the cooling tube (1), characterized in that knobs (9) of a defined distance and height as well as a wave-shaped (10) circumferential channel (11) are arranged on a roller (10). 25