DE102009042723B4 - Electrical cable comprising single wires of copper and a copper-tin alloy - Google Patents

Abstract

An electrical cable (1) comprising a plurality of copper (10) and copper-tin alloy (20) individual wires extending in the lengthwise direction of the cable (1), the individual wires (10, 20) being twisted forming a strand in which the strand is formed of x single wires (10) of copper and y single wires (20) of a copper-tin alloy, where x ≥ 1, y ≥ 1, and x + y ≥ 7, characterized in that - the cross-section of the strand is at most 0.2 mm 2, - that the individual wires (10) consisting of copper are subjected to an annealing step, - that the individual wires (20) consisting of the copper-tin alloy have a hard metallographic state and - that the cable (1) has a tensile strength of at least 80 N and a length-specific resistivity of not more than 125 Ω / km.

Description

The invention relates to an electrical cable according to the preamble of claim 1 (US Pat. JP 2008-166 141 A ).

The invention typically, but not exclusively, relates to electrical control cables or power cables used for power transmission.

Such cables are used in various fields of industry, such as in the automotive industry, where they are bundled together to supply power to various devices. These cables must therefore be as light as possible and have a small footprint, while at the same time having good mechanical strength.

Such cables are usually formed from a plurality of copper wires which are generally twisted to form a strand to increase the flexibility of the cable. They are surrounded by an insulating sheath, which is obtained for example by extrusion.

Known electrical cables use an oversized amount of copper as compared to the actual needs, which correspond to the amount of current to be transmitted by the cable. Specifically, almost half of the copper is used in the construction of these cables to increase the tensile strength of the cable. However, this quantity is oversized for the necessary electrical functions.

However, copper is becoming more and more expensive and it is important to find new cable assemblies that reduce the amount of copper used as much as possible.

From the publication US Pat. No. 6,674,011 B2 For example, an electrical cable is known comprising a unit of seven twisted strands forming strands, the seven strands being a copper-tin alloy. Although this strand has satisfactory mechanical and electrical properties, the size and weight of the strand are not significantly optimized.

The JP 2008-166 141 A describes a constructed of stranded individual wires electrical conductor. The individual wires consist partly of pure copper and partly of a copper alloy. For example, the conductor has five single wires of pure copper and two single wires of a copper alloy. The copper alloy may be a copper-tin alloy. The conductor has a cross-sectional area of 0.5 mm ² or less.

It is the object of the present invention to design the electrical cable described above so that it has a small footprint, low weight, as well as very good electrical and mechanical properties.

This object is achieved according to the characterizing features of claim 1.

The individual wires of the copper-tin alloy used are in a so-called hard metallographic state, or in other words, the individual wires are not subjected to an annealing step. Thus, the individual wires of the copper-tin alloy have low production costs, since the annealing step is not necessary. In contrast, the individual wires made of copper are subjected to an annealing step.

Due to the tensile strength of the cable of at least 80 N and its length-specific resistivity of at most 125 Ohm / km, the usual conditions of assembly and use as electrical control cables are met.

Preferably, the various individual wires are selected so that the cross-section of each single wire of copper and / or each single wire of a copper-tin alloy forming the strand is (are) substantially equal.

Advantageously, the individual wires are arranged in the strand so that they are in contact with each other over their entire length.

In a particular embodiment, the cross-section of the individual copper and copper-tin alloy wires and the percentage of tin in the alloy are defined by the following three equations:

Where S _{Cu is} the sum total of the cross-sections of the individual copper wires in mm ² , S _{alloy is} the total of the cross-sections of the individual wires of the copper-tin alloy in mm ² ,% Sn is the average of the percentages of tin of the individual wires of the copper-tin Alloy and ρCu is the specific electrical resistance of the copper in μOhm / cm (ρCu = 1.724 μOhm / cm).

Typically, the copper-tin alloy consists of copper, tin, possibly oxygen, and inevitable impurities.

According to a variant, and in order not to impair the electrical conductivity, the copper-tin alloy contains at most 0.60 wt .-% tin, preferably at most 0.30 wt .-% tin, and more preferably at most 0.20 wt. -% tin.

• – einen Zinngehalt von mindestens 1500 ppm und höchstens 2500 ppm, vorzugsweise von mindestens 1700 und höchstens 2200,
• – einen Sauerstoffgehalt von höchstens 400 ppm, vorzugsweise zwischen 100 und 300 ppm,
• – einen Gehalt an unvermeidlichen Verunreinigungen von höchstens 100 ppm, vorzugsweise von höchstens 65 ppm, und
• – der Rest des Gehalts der Legierung ist Kupfer.

As a preferred example, the copper-tin alloy contains:

• A tin content of at least 1500 ppm and not more than 2500 ppm, preferably at least 1700 and not more than 2200,
• An oxygen content of at most 400 ppm, preferably between 100 and 300 ppm,
• A content of unavoidable impurities of not more than 100 ppm, preferably not more than 65 ppm, and
• - the remainder of the alloy content is copper.

• – einen Gehalt an Zinn von mindestens 700 ppm und von höchstens 1200 ppm,
• – vorzugsweise zwischen 800 und 1000 ppm,
• – einen Gehalt an Sauerstoff von höchstens 50 ppm, vorzugsweise von höchstens 5 ppm,
• – einen Gehalt an unvermeidlichen Verunreinigungen von höchstens 100 ppm, und
• – der Rest des Gehalts der Legierung ist Kupfer.

When considering an alloy based on CuOF, for "oxygen-free" copper, the copper-tin alloy contains:

• A tin content of at least 700 ppm and not more than 1200 ppm,
• Preferably between 800 and 1000 ppm,
• An oxygen content of not more than 50 ppm, preferably not more than 5 ppm,
• - a content of unavoidable impurities of not more than 100 ppm, and
• - the remainder of the alloy content is copper.

The lower limit of the tin content of these alloys makes it possible to ensure sufficient mechanical resistance.

The abbreviation "ppm" in the present specification means "mass per million". In other words, the amount (or content) x is expressed in ppm of an element z with respect to the total weight of the alloy.

The cable according to the invention comprises a strand having a cross section of at most 0.2 mm ² .

In addition, the cable may have an insulating sheath surrounding the strand along the cable.

Further features and advantages of the present invention will become apparent from the following embodiments with reference to the sole annotated figure of the drawing, wherein the examples and the drawings are purely illustrative and not restrictive.

The drawing schematically illustrates a structure of an electric cable according to the present invention in cross section.

It should be noted in advance that only the essential elements for understanding the invention are shown schematically, without regard to the scale.

The drawing shows an electrical, so-called control cable 1 according to a particular embodiment of the invention, containing seven individual wires of substantially the same cross-section. For example, these seven individual wires are on three individual wires 10 made of copper and four individual wires 20 distributed from a copper-tin alloy. These seven individual wires are also of an insulating sleeve 30 surrounded by a circular outer cross section.

The diameter of the cable, which contains the strand of seven individual wires, lies together with the insulating cover 30 typically of the order of 1.6 mm, and the individual wires of copper and of the copper-tin alloy each have a diameter of 0.173 mm. In general, the diameter of the individual wires forming the strand is between 0.10 mm and 0.30 mm.

Typically, the number of individual wires, the cross-section of the individual wires, and the content of copper-tin alloy tin are chosen such that on the one hand to obtain a tensile strength of more than 80 N and on the other hand to obtain a length-related electrical resistance of less than or equal to 125 ohms / km according to the present invention.

Comparative Examples

In order to demonstrate the advantages of the electrical cable according to the present invention, the mechanical and electrical properties of strands according to the invention (experiment I1) and according to the prior art (experiments C1 to C3) are compared below.

Mechanical property: the tensile strength (mechanical resistance)

• – 5 Proben eines elektrischen Leiterdrahts einer Länge von 200 mm entnehmen,
• – die Backen des Dynamometers in 100 mm Abstand zueinander anordnen,
• – den oberen Bereich der Probe bzw. ihren unteren Bereich in der oberen und unteren Backe des Dynamometers anordnen, und
• – den Zugtest bis zum Reißen der Probe durchführen.

Tensile strength is determined according to standard NFEN1002-1 by means of a dynamometer whose sliding speed of the lower jaw is 100 ± 10 mm / min. The operation is:

• - take 5 samples of an electrical conductor wire of 200 mm length,
• - arrange the jaws of the dynamometer 100 mm apart,
• - arrange the upper part of the sample or its lower part in the upper and lower jaw of the dynamometer, and
• - carry out the tensile test until the sample has ruptured.

Electrical property: the length-specific electrical resistance

The length-specific electrical resistance is determined according to the standard CEI 60468: 1974.

The structure of each strand and the properties are shown in the following Table 1 in detail. Table 1 tries C1 C2 C3 I1 Number of individual wires made of copper 7 6 0 3 Number of individual wires made of steel 0 1 0 0 Number of strands of copper-tin alloy 0 0 7 4 % of tin in the copper-tin alloy / / 0.33 0.33 Nominal diameter of each single wire (mm) 0.252 0,220 0,180 0.173 Cross section of the strand formed by the twisted strands (mm ² ) 0.349 0.266 0,178 0,165 Tear resistance (N) 80 80 131 93 maximum length-related resistivity (ohms / km) 50 72 124 124 Cross-sectional gain with respect to experiment C3 (%) -96% -50% 0 7.3%

In the examples mentioned in Table 1, the cross sections of each single wire are made of the copper-tin alloy and copper.

In other embodiments, the cross sections of each single wire may be different from the copper-tin alloy and each copper single wire.

The cable obtained according to the invention is inexpensive due to the reduction in the amount of copper used, and it also has very good electrical and mechanical properties.

Claims (7)

Electric cable ( 1 ), which consists of several individual copper wires ( 10 ) and a copper-tin alloy ( 20 ) extending in the longitudinal direction of the cable ( 1 ), wherein the individual wires ( 10 . 20 ) are twisted to form a strand in which the strand of x individual wires ( 10 ) of copper and of y individual wires ( 20 ) is formed of a copper-tin alloy, with x ≥ 1, y ≥ 1, and x + y ≥ 7, characterized in that - the cross-section of the strand is at most 0.2 mm ² , - that consisting of copper Individual wires ( 10 ) are subjected to an annealing step, that the individual wires made of the copper-tin alloy ( 20 ) have a hard metallographic state and - that the cable ( 1 ) has a tensile strength of at least 80 N and a length-specific resistivity of at most 125 Ω / km. Electrical cable according to claim 1, characterized in that the strand of x individual wires ( 10 ) of copper and of y individual wires ( 20 ) is formed of the copper-tin alloy, with x + y = 7. Electrical cable according to claim 1, characterized in that the strand of x individual wires ( 10 ) of copper and of y individual wires ( 20 ) is formed of the copper-tin alloy, with 2 ≦ x ≦ 4, and 3 ≦ y ≦ 5. Electrical cable according to one of claims 1 to 3, characterized in that the copper-tin alloy contains at most 0.60 wt .-% tin. Electrical cable according to one of the preceding claims, characterized in that the cross-section of each individual wire ( 10 ) is equal to copper. Electrical cable according to one of the preceding claims, characterized in that the cross-section of each individual wire ( 20 ) is equal to the copper-tin alloy. Electrical cable according to one of the preceding claims, characterized in that it also comprises an insulating sleeve surrounding the strand along the cable ( 30 ) having.

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