WO2014161951A1

WO2014161951A1 - Shaped wire element

Info

Publication number: WO2014161951A1
Application number: PCT/EP2014/056723
Authority: WO
Inventors: Robert Kopetzky
Original assignee: Robert Kopetzky
Priority date: 2013-04-03
Filing date: 2014-04-03
Publication date: 2014-10-09
Also published as: DE102013005686A1; EP2981353A1

Abstract

The invention relates to a shaped wire element, produced by a forming process from at least one wire and designed to allow the passage of a flowing mass. According to the invention the wire has a polygonal cross-section which is constant along its length, and is disposed in the shaped wire element in such a way that the spatial orientation of the wire undergoes continuous change along its length.

Description

Wire moldings

The invention relates to a manufactured by forming, to be flowed through by a mass flow wire molding of at least one wire.

Wire shaped bodies of the type mentioned are known for a long time. They are used for a variety of purposes, such as cooling elements, filter cartridges, and the like. Conventionally, a known wire molding is made of a wire having a round cross section. For this purpose, the wire is usually entangled, knitted or woven to a precursor. Subsequently, the precursor is converted in a forming device by plastic forming to form a wire shaped body, wherein the shaped wire body is formed according to the negative shape of the reforwarding device.

Wires with a round cross-section are used in particular because they are particularly suitable for the various processes that are commonly used for the preparation of the precursors.

So far, the use of round wires was also considered particularly advantageous because round wire cross-sections of mass flows, such as a liquid flow or a gas flow, which are to flow through the wire shaped body, can be flowed around particularly well due to the rounded surfaces.

For some time, however, attempts have been made to produce wire shaped bodies which, with the lowest possible weight, have a flow behavior comparable to that of conventional wire shaped bodies. Based on this problem, it is now an object of the invention to provide a wire molding, which has a significantly lower weight compared to known wire moldings with constant flow behavior.

According to the invention, this object is achieved by a shaped wire body with the features according to claim 1 and in particular by the fact that the wire over its length considered consistent, polygonal cross-sectional shape and that the wire is arranged in the wire shaped body such that the wire over its length undergoes a constant change in its spatial orientation.

Unlike previously customary, it is proposed according to the invention to use a wire for the shaped wire body, which has a constant polygonal cross-sectional shape over its length, instead of using a wire whose cross-section is round in shape. Thus, it has been shown that the use of a cross-section polygonal wire constantly changes its spatial orientation over the length considered in the wire shaped body, in the wire shaped body targeted laminar and turbulent flows can be generated, which influence the flow behavior targeted. The turbulent flows in turn lead to a significant increase in the flow resistance of the shaped wire body according to the invention compared with shaped wire bodies, which consist of wires with round cross-sectional shapes. are made.

In order to realize the same flow behavior, in particular a nearly identical flow resistance in the wire shaped body according to the invention, due to the intrinsically unfavorable flow behavior of the wires with angular cross section, the length of necessary wire can be reduced compared to conventional wire shaped bodies of wires with a round cross section, while still approximately Maintaining constant flow resistance can w.

The fact that a shorter wire length can be used in the wire molding according to the invention, in turn, leads to a reduction in the weight of the wire molding according to the invention compared to the weight of a conventional wire molding of wires with a round cross section.

If, for example, a wire-formed body is used as reference, which is made of a round wire with a wire diameter of one millimeter and a length of 1000 mm, one needs for a wire shaped body according to the invention, for example, from a square in cross-section wire with a edge length of each 0th , 89 mm only a length of 678 mm, resulting in a weight savings of approximately 32%. With a cross-sectionally square wire with an edge length of 0.6 mm and a length of 1000 mm results in a weight saving of approximately 55% with approximately the same flow resistance.

With the wire shaped body according to the invention, it is possible to significantly save material while maintaining a constant flow behavior. It is also possible to influence and adjust the heat transfer behavior by selective selection of the cross-sectional shapes and wire lengths, the flow behavior and, as will also be explained, the heat transfer behavior.

Further advantages of the invention will become apparent from the following description and the appended claims. Thus, in a particularly preferred embodiment of the inventive wire shaped body proposed to use a wire having a rectangular or square cross-sectional shape, since these cross-sectional shapes are easily made by pulling the wire. In order to further influence the flow behavior, in particular the flow resistance, it is further proposed to form the shaped wire body from at least two wires, which are twisted together to form a strand before forming the shaped wire body. Preferably, in this embodiment, the wires have identical cross-sectional shapes.

The weight saving can be in a range of 25 to 60% in a wire molding according to the invention compared with a wire molding, which is made of a wire with a round cross-section. The invention will be briefly explained with reference to two embodiments of a shaped wire body according to the invention in comparison to a conventional wire shaped body.

In the following table are different data of a conventional wire formed body made of a wire having a round cross section. in the Comparison to two embodiments shown, in which one wire with square cross section is used:

In the table are the abbreviations for the following sizes: d Duranderesser of the round wire

a edge length of the square in cross-section wire

1 length of the wire used for the shaped wire body

A _p cross-sectional area

C _w drag coefficient

Material weight of material based on 100%

APs _tr ö _m flow resistance based on 100%

AE heat absorbed and dissipated amount of heat related to 100%

The reference used wire shaped body is made of a wire with a round cross-section. The wire has a diameter d of 1.00 mm and a length 1 of 1000 mm. This results in a flow around cross-sectional area A _p of 0.79 mm ² at a resistance coefficient C _w of 1, 2.

In the first embodiment, the wire molding is made of a square-section wire. The wire cross-section has an edge length a of 0.79 mm, so that also results in a cross-sectional area A _p of 0.79 mm ² . Due to the higher resistance coefficient C _w of 2.0 results in an approximately constant flow resistance of 100.27% based on the reference wire shaped body, a necessary length for the wire 1 of only 678 mm, so that, also relative to the reference Re- Drah tformkörper only 67.92% material must be used, resulting in a material savings of 32.08%. Only the amount of heat AE _induced by the shaped wire body according to the first _{exemplary embodiment} is only 76.57%, based on the reference wire shaped body. In the second embodiment, the wire molding is also made of a square-section wire. However, the wire cross-section here has an edge length a of only 0.60 mm, so that only a cross-sectional area A _p of 0.36 mm ² results. However, owing to the higher resistance coefficient C _w of 2.0, a flow resistance of 100.00% with respect to the reference wire molding also results in the second embodiment, the necessary length for the wire 1 corresponding to the length of the wire of the reference wire molding, namely 1000 mm. As a result, based on the reference wire molded body, only a material input of 45.84% results, so that a material saving of 54. 16% is achieved. Only the absorbed by the wire shaped body according to the second exemplary embodiment amount of heat AE _heat is only 76.39% based on the reference wire shaped body. If now a higher flow resistance or a higher amount of heat to be absorbed by the shaped wire body, only the length of the wire used for the shaped wire body or its cross-sectional dimensions must be adjusted accordingly. As the table is impressive to see can be adjusted by comparatively simple measures, such as a change in the cross-sectional dimensions or a change in the wire length very targeted the Strömungswiders and the amount of heat dissipated.

Claims

claims

1. By uniforms produced, to be flowed through by a mass flow wire molding of at least one wire,

characterized,

that the wire has a constant, polygonal cross-sectional shape over its length, and that the wire is arranged in the wire-formed body such that the wire experiences a continuous change in its spatial orientation over its length.

2. Wire ormkörper according to claim 1, characterized in that the wire has a rectangular or square cross-sectional shape.

3. wire molding according to claim 1 or 2, characterized in that the wire molding is formed from at least two wires, which are twisted together before forming the wire molding into a strand.

4. Wire molding according to claim 3, characterized in that the wires have identical Q uerschni t ts form.

5. Wire molding according to one of the preceding claims, characterized in that the weight of the shaped wire body is less than the weight of a made of a wire with a round cross section wire molding with identical flow resistance, wherein the weight reduction is in a range of 25 to 60%.