DE202018100075U1 - Copper-zinc alloy - Google Patents

Abstract

Copper-zinc alloy for producing electrically conductive components, such as contacts, consisting of:
Cu: 62.5-67% by weight,
Sn: 0.25-1.0 wt%,
Si: 0.015 - 0.15 wt.%,
at least two silicide-forming elements from the group Mn, Fe, Ni and Al, each with max. 0.15% by weight, the sum of these elements not exceeding 0.6% by weight,
Remaining Zn plus unavoidable impurities.

Description

The invention relates to a copper-zinc alloy and a copper-zinc alloy product produced from such an alloy.

The invention relates to a special brass alloy. Special brass alloys are used to produce a wide variety of products. A typical application, for the use of special brass alloy products are bearing parts, engine and transmission parts, such as synchronizer rings and the like, and fittings, especially for drinking water applications. Brass alloy products are also used for electrical and refrigeration applications, for example, for the manufacture of connector shoes, contact terminals or the like. Cooling applications utilize the good thermal conductivity of brass alloy products. These brass alloys have a high copper content due to the known good thermal conductivity of copper and are only correspondingly low alloyed. Special brass alloys have a significantly lower thermal conductivity.

If a brass alloy should have particularly good electrically conductive properties, the Cu content should be selected to be correspondingly high. However, the electrical conductivity of such a product decreases with increasing zinc content. For this reason, for special brass alloy products in which a good electrical conductivity is in the foreground, such alloys are used which have a Zn content of typically not more than 5 to 10 wt .-%. In addition to the elements copper and zinc, one or more of the following elements are involved in the construction of special brass alloys: Al, Sn, Si, Ni, Fe and / or Pb. Each of these elements has a different influence on the properties of the special brass alloy product produced from the alloy. It should be noted that one and the same alloying element, depending on its participation, may be responsible for different properties with regard to the processability of the alloy and with respect to the properties of a special brass alloy product produced therefrom. The same applies to the processability of the alloy. Due to the large number of different applications of special brass alloy products, a large number of special brass alloys differing in their alloy composition are also known. These differ, for example, in their strength values, their machinability, their surface workability, their thermal conductivity, their modulus of elasticity, their thermal stability and the like. In most cases, the previously known special brass alloys have been developed with regard to their composition for very specific purposes.

A special brass alloy from which special brass alloy products are to be produced for electrical applications not only have to have sufficient electrical conductivity, but also have to be able to produce the desired products to have a good machinability and workability, as well as sufficient strength values. With regard to processability of the alloy, it should be able to be produced using standard processing steps so that the costs of special brass alloy products produced therefrom are not made more expensive by expensive and possibly unusual process management steps.

Out DE 20 2017 103 901 U1 a special brass alloy for electrical and / or cooling technology applications has become known. This contains 58.5-62% by weight of Cu, 0.03-0.18% by weight of Pb, 0.3-1.0% by weight of Fe, 0.3-1.2% by weight. Mn, 0.25-0.9 wt% Ni, 0.6-1.3 wt% Al, 0.15-0.5 wt% Cr, max. 0.1% by weight of Sn, max. 0.05 wt .-% Si with a balance of Zn plus unavoidable impurities. Although this known special brass alloy has sufficient thermal conductivity for the cooling technology applications provided for this purpose and sufficient electrical conductivity for a number of applications, it would be desirable if not only the electrical conductivity but also the extrudability and the machinability could be improved in order to increase the manufacturability of electrical Components such as contacts, sockets or the like to produce better. In addition, the alloy product made from such an alloy should have good cold workability properties, such as good cold drawability properties, in order to be able to provide the formed semi-finished product with higher strength values for the end product in this way.

Thus, the invention has for its object to propose a copper-zinc alloy that meets these requirements.

• Cu: 62,5 - 67 Gew.-%,
• Sn: 0,25 - 1,0 Gew.-%,
• Si: 0,015 - 0,15 Gew.-%,
• wenigstens zwei Silizid bildende Elemente aus der Gruppe Mn, Fe, Ni und Al mit jeweils max. 0,15 Gew.-%, wobei die Summe dieser Elemente 0,6 Gew.-% nicht überschreitet,
• Rest Zn nebst unvermeidbaren Verunreinigungen.

This object is achieved according to the invention by a copper-zinc alloy for producing electrically conductive components, such as contacts, consisting of:

• Cu: 62.5-67% by weight,
• Sn: 0.25-1.0 wt%,
• Si: 0.015 - 0.15 wt.%,
• at least two silicide-forming elements from the group Mn, Fe, Ni and Al, each with max. 0.15% by weight, the sum of these elements not exceeding 0.6% by weight,
• Remaining Zn plus unavoidable impurities.

This copper-zinc alloy is characterized by its special alloy composition. On the one hand, the Zn content of 31-37% by weight and the significant contribution of the element Sn to the structure of the alloy are 0.5-1.0% by weight. Due to the relatively high Zn content, it was surprisingly found that nevertheless the electrical conductivity meets the requirements imposed on a product made from this alloy and even exceeds the conductivity of previously known special brass alloys. Si is involved in the alloy at 0.015-0.15 wt%. The Si in the alloy serves to form silicides as fine precipitates in the microstructure. The size of the silicides is typically less than 1 μm on average. If the silicides exceed a certain size, this has adverse effects on the polishability, coatability and / or solderability of the surface of the alloy product made of the alloy. A higher Si content can not improve the particular properties of the alloy according to the invention. Rather, this could adversely affect the desired good electrical conductivity. From the group of elements Mn, Fe, Ni and Al as silicide-forming elements at least two elements are involved in the construction of the alloy. Together with Si, these elements form finely divided mixed silicides which have a positive effect on the abrasion resistance of the product made from the alloy. These silicides are finely divided particles in the matrix. The proportion of these elements in the structure of the alloy is limited, to max. 0.15 wt .-% per element, wherein the sum of these elements does not exceed 0.6 wt .-%. The elements Fe, Ni and Al are preferably involved in the construction of the alloy. Mn can be part of the alloy as a silicide-forming agent. The elements Fe, Ni and Al are preferably provided as silicide formers, which typically form mixed silicides. It is provided in one embodiment that the Ni and Al components are each about the same size, while the Fe content is only 40 - 60% of the Ni or Al content. In a preferred embodiment, the Fe content is about 50% of the Ni or Al content. With this particular combination of the silicides Fe, Ni and Al, together with the Si content between 0.015-0.15% by weight, the extent to which the desired particularly good electrical conductivity of the product made from the alloy does not have a significant adverse effect. Nevertheless, these give the alloy product its desired strength values.

Unexpectedly and surprisingly, this alloy or an alloy product produced from this alloy has shown that this not only has a particularly fine grain (typically 10-100 μm) but is also very readily extrudable or heat-formable, and can be cold-worked well by cold working and has a good machinability and still has a special brasses of the type in question very good electrical conductivity of more than 12 MS / m (20% IACS). This is moored at the relatively high Sn content with simultaneously limited proportions of the silicide-forming elements.

What is of interest for electrical applications of a special brass alloy product produced from this alloy is its particularly good galvanic coatability. In some applications, such products are coated with an electrically highly conductive metal layer, a coating whose electrical conductivity significantly exceeds that of the product produced from the brass alloy. Such a metal layer is typically applied by electroplating. This requires not only a certain conductivity of the special brass alloy product, but above all, that an applied thereto galvanic order adheres to it permanently and evenly over the surface. This is justified, in particular, in the uniform fine-grained microstructure occurring in this special brass alloy. This is the case with products made from this alloy. A coating of the brass alloy product can also serve for wear protection. Furthermore, coatings can be used to improve certain properties of the brass alloy product on the surface, such as better solderability, for example for attaching contacts, thermal insulation for thermal protection of the special brass alloy product or as an adhesion-promoting layer for a further coating.

In addition, the modulus of elasticity is sufficiently high, so that products with resilient properties, such as connector shoes can be made as contacts from this brass alloy. With an E-modulus of more than 100 to 120 GPa, this lies in the size range of the E-modules, which are low alloyed copper-zinc binary alloys are known, as is typically used for electrical applications, which sometimes involves applied spring force. This brass alloy can be used to produce alloy products with electrical conductivity greater than 12 MS / m (20% IACS). This achieves electrical conductivity values which are generally higher than other special brass alloys with a Zn content of 30% by weight or more and which are sufficient for many applications. This is combined with alloy products made of this alloy, with strength values, as they are otherwise known only by specially designed for this purpose special brass alloys, but then do not have in the other positive properties of this alloy or a product produced therefrom.

Not insignificant in the produced from this special brass alloy special brass alloy product, especially in electrical applications, the same good solderability.

It should be emphasized that this copper-zinc alloy due to the small number of elements involved in the construction of the alloy their simple chemical structure. This also includes that the alloy is Cr-free. The alloy is also typically Pb-free, with a Pb content of max. 0.1 wt .-% is allowed. It can not always be avoided that small quantities of Pb are introduced into the alloy as a result of carry-over or the use of recycled material. Within the permitted range, Pb does not adversely affect the above-described positive properties of this copper-zinc alloy. Furthermore, the use of elements such as P, S, Be, Te and others is dispensed with - elements that are often used in addition to Cr to achieve certain alloy properties in other special brass alloys to achieve certain strength or processing properties. This, too, justifies the surprising result that the above-described positive properties of a product made from the alloy, although the alloy is composed of only a few elements, assuming that the elements are involved with the specified proportions of the alloy. The use of only a small number of elements in the structure of the alloy simplifies the manufacturing process. Danger of elemental carryover for other alloys is avoided in commercial production since the elements involved in the assembly of the alloy are standard elements of any special brass alloy.

The particularly good machinability of an alloy product made from this alloy can be given with an index of 60-70 and in a specific embodiment of more than 80.

• Cu: 64 - 66 Gew.-%,
• Sn: 0,3 - 0,7 Gew.-%,
• Si: 0,03 - 0,1 Gew.-%.

The copper-zinc alloy according to the invention preferably has the following composition:

• Cu: 64-66% by weight,
• Sn: 0.3-0.7 wt%,
• Si: 0.03-0.1 wt%.

• Cu: 64,5 - 66 Gew.-%,
• Sn: 0,4 - 0,6 Gew.-%,
• Si: 0,03 - 0,08 Gew.-%,
• wenigstens zwei Silizid bildende Elemente aus der Gruppe Mn, Fe,
• Ni und Al mit jeweils max. 0,1 Gew.-%, wobei die Summe dieser Elemente 0,4 Gew.-% nicht überschreitet,
• Rest Zn nebst unvermeidbaren Verunreinigungen.

According to one embodiment, the Sn and Si content is further limited, as is the level of silicide-forming elements. Such an alloy is composed as follows:

• Cu: 64.5-66% by weight,
• Sn: 0.4-0.6 wt%,
• Si: 0.03-0.08 wt%,
• at least two silicide-forming elements from the group Mn, Fe,
• Ni and Al with max. 0.1% by weight, the sum of these elements not exceeding 0.4% by weight,
• Remaining Zn plus unavoidable impurities.

The preferred Zn content is between 32 and 36 wt .-%.

The invention is described below with reference to an embodiment in comparison to three comparative alloys. The alloy according to the invention was produced in addition to three comparative alloys and extruded. The composition of the tested alloys is shown in the table below: Cu pb sn Fe Mn Ni AI Si Cr Zn A 65 - 0.5 0,035 - 0.07 0.07 0.06 - rest 1 60.3 0.11 - 0.5 0.8 0.5 0.9 - 0.24 rest 2 60 0.1 0.08 0.05 0,025 0.01 0.03 0.005 0.01 rest 3 58.3 0.1 0.08 0.1 0,008 0.01 0.01 0.005 0.02 rest (In% by weight)

• 0,2% Dehngrenze: 180 - 250 N/mm²,
• Zugfestigkeit: ca. 600 N/mm²,
• Bruchdehnung: ca. 30%,
• Härte: 80 - 130 HBW.

In the above table, the alloy according to the invention is alloy A, while the comparative alloys are alloy 1, alloy 2 and alloy 3. In the state of extrusion, the alloy according to the invention has the following strength values:

• 0.2% proof stress: 180-250 N / mm ² ,
• Tensile strength: approx. 600 N / mm ² ,
• Elongation at break: approx. 30%,
• Hardness: 80 - 130 HBW.

Good cold drawability and concomitant work hardening with the result of introducing increased strength values into the alloy product can be represented on the cold drawn state of the extrusion rod in a first step with 20% reduction in cross section and in a second step with a 35% reduction in cross section:

• 0,2% Dehngrenze: 400 - 450 Nmm²,
• Zugfestigkeit: ca. 500 - 600 N/mm²,
• Bruchdehnung: ca. 8 - 15%,
• Härte: 120 - 150 HB.

Strength values of the cold drawn rod with 20% reduction in cross section:

• 0.2% proof stress: 400 - 450 Nmm ² ,
• Tensile strength: approx. 500 - 600 N / mm ² ,
• Elongation at break: approx. 8 - 15%,
• Hardness: 120 - 150 HB.

• 0,2% Dehngrenze: 450 - 500 Nmm²,
• Zugfestigkeit: ca. 750 N/mm²,
• Bruchdehnung: ca. 10%,
• Härte: 150 - 200 HB.

Strength values of the cold drawn rod with 35% reduction in cross section:

• 0.2% proof stress: 450 - 500 Nmm ² ,
• Tensile strength: approx. 750 N / mm ² ,
• Elongation at break: approx. 10%,
• Hardness: 150 - 200 HB.

The microstructure of the alloy according to the invention has predominantly α-phase in the matrix at room temperature. At hot forming temperatures there is a sufficient proportion of β-phase. The grain structure is small at room temperature with a mean grain size of 10 to 100 microns. The silicides are finely distributed as fine precipitates that form from the press heat.

The properties of the inventive alloy A at room temperature compared to the three comparative alloys are shown in the following table: Properties after drawing [20% deformation] unit Alloy 1 Alloy 2 Alloy 3 Alloy A extrudability Well Well Well Very well Kaltziehbarkeit Well Very well Well Well machinability index 80 20 25 ≥ 80 Electrolytic polishing Well Very well medium Well Galvanic polishing Very well Very well Well Very well thermal conductivity [W / (m * K)] 100-110 385 ≥ 310 ≥ 100 Electric conductivity [MS / m] 9.1 56 ≤ 43 ≥ 12 (20% IACS) Modulus [GPa] 96 107 110-130 100-120 0.2% proof stress [MPa] ≥ 550 ≥ 240 ≥ 350 400 tensile strenght [MPa] ≥ 650 ≥ 280 ≥ 420 520-570 elongation [%] ≥ 15 ≥8 ≥ 8 6 - 11.3

This comparison shows that the alloy according to the invention (alloy A) has particularly good properties in the parameters relevant for electrical applications. However, this is associated with a particularly high modulus of elasticity and very good strength values. For this reason, this alloy is above all also suitable for the production of electrical contact elements which must have material-elastic properties.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 202017103901 U1 [0005]

Claims (13)

Copper-zinc alloy for producing electrically conductive components, such as contacts, consisting of: Cu: 62.5-67% by weight, Sn: 0.25-1.0 wt%, Si: 0.015 - 0.15 wt.%, at least two silicide-forming elements from the group Mn, Fe, Ni and Al, each with max. 0.15% by weight, the sum of these elements not exceeding 0.6% by weight, Remaining Zn plus unavoidable impurities. Copper-zinc alloy after Claim 1 with Cu: 64 - 66.5 wt .-%, Sn: 0.3 - 0.7 wt .-%, Si: 0.03 - 0.1 wt .-%. Copper-zinc alloy after Claim 2 with Cu: 64.5-66 wt.%, Sn: 0.4-0.6 wt.%, Si: 0.03-0.8 wt.%, at least two silicide-forming elements from the group Mn , Fe, Ni and Al with max. 0.1 wt .-%, wherein the sum of these elements does not exceed 0.4 wt .-%, balance Zn plus unavoidable impurities. Copper-zinc alloy after one of Claims 1 to 3 , characterized in that the alloy Zn contains 32-36 wt .-%. Copper-zinc alloy after one of Claims 1 to 4 characterized in that among the silicide-forming elements in the alloy are Fe, Ni and Al, wherein the proportions of Ni and Al are each about the same and the Fe content is 40% to 60% of the Ni and Al contents, respectively is. Copper-zinc alloy after the Claim 5 , characterized in that the Ni and Al content is 0.04 to 0.1 wt% and Fe is 0.02 to 0.05 wt%, respectively. Copper-zinc alloy after Claim 6 characterized in that the Ni content and the Al content are respectively 0.06 to 0.08 wt% and the Fe content is 0.03 to 0.04 wt%. Copper-zinc alloy after one of Claims 1 to 7 , characterized in that the alloy is Cr-free. Copper-zinc alloy product made from a copper-zinc alloy according to one of Claims 1 to 8th , characterized in that the matrix at room temperature largely contains α-phase. Copper-zinc alloy product after Claim 9 , characterized in that the mean grain size of the structure is between 10 and 100 microns. Copper-zinc alloy product after Claim 9 or 10 , characterized in that its electrical conductivity is at least 12 MS / m (20% IACS). Copper-zinc alloy product according to one of Claims 9 to 11 , characterized in that the product is cold worked from a semi-finished product by drawing it having a cross-sectional reduction of about 20% and having the following strength values: 0.2% proof stress: 400-450 Nmm ² , tensile strength: about 500-600 N / mm ² , Elongation at break: approx. 8 -15%, Hardness: 120 - 150 HB. Copper-zinc alloy product according to one of Claims 9 to 11 characterized in that the product is cold worked from a semi-finished product by drawing it having a cross-sectional reduction of about 35% and having the following strength values: 0.2% proof stress: 450-500 Nmm ² , tensile strength: about 750 N / mm ² , elongation at break : approx. 10%, hardness: 150 - 200 HB.