The disclosure relates to a connector with a connector housing and at least one electrical contact element to establish an electrical and mechanical connection between two electrical lines or an electrical line and a device, in particular in an industrial environment.
Connectors and mating connectors are used to establish an electrical and mechanical connection between two electrical lines or an electrical line and a device, in particular in an industrial environment. Electrical contact elements are predominantly used in these connectors. The contact elements are needed to establish an electrical connection between an electrical conductor, in particular a stranded conductor, and a connection end of a pin contact or socket contact.
Crimping connection technology is frequently chosen to connect stranded conductors to an electrical contact element. The contact elements therefore have, at their conductor connection end, an axial bore in which the stripped end of the stranded conductor is inserted and is tightly squeezed by crimping. Screw connections, a cage clamp connection, press-in technology and different solder variants can also be provided as the connection technology.
DE 20 2012 101 303 U1 discloses a connector having a cylindrical connector housing. The cylindrical connector housing is produced with the aid of machining technology.
DE 10 2014 104 406 A1 discloses a contact element which is produced from solid material using a turning technique.
So-called rotary indexing machines, as described for example in WO 99/43464 A2, are used as manufacturing machines, in particular for contact elements. Such manufacturing machines have a plurality of workstations through which a workpiece or a blank pass in succession.
To improve the processing of the material to produce a clamping body, in particular within the context of a machining process, it is usual to add lead to the material of the clamping body. The connector housing of DE 20 2012 101 303 U1 and the contact element of DE 10 2014 104 406 A1 could hitherto only be produced from lead-containing materials. These lead additions are, however, disadvantageous in terms of satisfying the EU guidelines for lead-free products (regulations prohibiting the use of certain substances in the electrical industry or end-of-life vehicle regulations).
For better machinability, current solutions have a lead content of up to 4 weight percent (wt %). The mechanical and electrical properties of these contact materials are well established. Alternative solutions must therefore be based on these properties.
Lead is one of the most toxic heavy metals. If lead makes its way into the environment, it can cause substantial damage there. It therefore makes sense to omit lead to the greatest extent possible for ecological reasons.
An object of the disclosure is to provide a connector which conforms to EU guidelines and is environmentally acceptable, whilst exhibiting good processability during its production.
The object is achieved by the subject matter as claimed.
The disclosed connector consists at least of a connector housing and at least one electrical contact element, wherein the connector generally has a plurality of electrical contact elements, which can be configured for transmitting high currents but also for rapid data transfer. In particular, the geometry of the contact elements is adapted to their respective task. The connector housing and/or the electrical contact element has or have a lead content of less than 0.1 weight percent (<0.1 wt %). Such a connector is deemed to be particularly environmentally friendly.
Tests have shown that the contact elements or the blanks from which they are manufactured must have a tensile strength Rm of ≥300 MPa and an elongation at break A11.3 of ≥5% according to EN ISO 6892-1 in order to satisfy industrial requirements.
The connector housing and/or the electrical contact element therefore consist of copper or a copper alloy whereof the lead content is <0.1 weight percent, wherein the connector housing and/or the electrical contact element has or have a tensile strength Rm of ≥300 MPa and an elongation at break A11.3≥ of 5%.
The tensile strength is one of a plurality of strength values of a material, the maximum mechanical tensile strength which the material withstands. In most cases, it is calculated from the results of the tensile test as the maximally reached tensile force Fmax in relation to the original cross-section A0 of the standardized tensile specimen.
In materials science, the elongation at break A is a value which indicates the residual elongation of the tensile specimen after breakage in relation to the initial measured length. It characterizes the deformability (or ductility) of a material and can be defined differently and also denoted by different symbols according to the characteristic mechanical behavior of the material types.
The elongation at break is the residual change in length ΔL in relation to the initial measured length L0 of a specimen in a tensile test after breakage has taken place A=ΔL/L0. The initial measured length L0 is specified prior to the tensile test by measuring marks on the tensile specimen.
The connector housing or the electrical contact element, or the connector housing and the electrical contact element, preferably consists or consist of a copper zinc alloy.
The connector housing and/or the electrical contact element preferably consists of
The respective boundaries are each included in the value ranges.
In a particularly advantageous variant, the connector housing or the electrical contact element consists of CuZn32Mn2Si1Al or CuZn34Mn2SiAlNi or CuZn36 or CuZn37 or CuZn38 or CuZn39 or CuZn40 or CuZn42 or CuNi9Zn41FeMn or Cu-ETP or a mixture of the above-mentioned substances. Alternatively, the connector housing and the electrical contact element consist of CuZn32Mn2Si1Al or CuZn34Mn2SiAlNi or CuZn36 or CuZn37 or CuZn38 or CuZn39 or CuZn40 or CuZn42 or CuNi9Zn41FeMn or Cu-ETP or a mixture of the above-mentioned substances. Cu-ETP is an oxygen-containing (tough-pitch) copper produced by electrolytic refining, which has very good conductivity for heat and electricity (in the soft state at least 57 m/Ω·mm2).
The substances preferably contain a lead-free admixture. The machining of the above-mentioned materials is thereby improved. The lead-free admixture preferably represents a content of 0.5 up to and including 1.5 weight percent. It is particularly advantageous if the lead-free admixture represents a content of less than or equal to 1 weight percent. It is particularly advantageous if the lead-free admixture contains Fe and/or Sn and/or Si and/or Ni.
All contact elements and metallic connector housings currently found in the product portfolio of the HARTING Technology Group, and the geometries thereof, can be realized using the above-mentioned materials. In this case, different geometries can be realized by different substances, for example. The contact elements and/or connector housing are realized, in particular, with the aid of turning technology (turning technique).
Turning, also referred to as turning technique or turning process within the context of the present document, is one of the most important manufacturing techniques in machining technology, together with boring, milling and grinding. As in all of these techniques, material is removed from a workpiece in order to produce the desired form. In turning, the workpiece—the turned part—rotates about its own axis, whilst the tool—the turning tool—moves along the contour to be produced on the workpiece. The corresponding machine tool is a lathe.
The electrical contact is generally prepared from solid material. To this end, the turning technology is used on cam- or CNC-controlled machines. However, machining procedures are also needed for the slot in the connection region of the contact element.
The contact region of the contact element can be designed both as a pin contact or as a socket contact. The connection region is designed, for example, as a crimp connection, in particular to enable electrical contacting of stranded conductors. The crimp connection is realized, in particular, by a boring technique on the contact element.
In the crimping procedure, the strands of an electrical conductor cable to be connected are inserted into the connection region designed as a hollow cylinder. The hollow cylinder is slotted in the axial direction and is thus open at the side. With the aid of a suitable crimping tool, a force is exerted on the lateral surface of the slotted hollow cylinder so that the opposing slot edges are bent and rolled inwards. The compressed strands of the conductor cable are now located in the residually deformed connection region of the contact element.
The contact element can be manufactured from a blank, for example, which passes through at least 8 workstations on the manufacturing machine in one production cycle. In these at least 8 workstations, the following manufacturing steps are carried out on the blank, which together produce a finished contact element:
The blank from which the contact element is manufactured has a connection region and a mating region. The connection region later serves for connecting an electrical conductor to the contact element. The mating region serves for establishing electrical contact with a corresponding mating contact element.
In the manufacturing process for a so-called pin contact
In the manufacturing process for a so-called socket contact
The contact element is advantageously provided with an outer coating, for example to optimize the electrical conductivity or the current-carrying capacity of the contact element. This can be, for example, a silver tungsten alloy, which can be deposited in particular using an electroless galvanic coating technique. The layer thickness of the deposited silver tungsten alloy can be 0.05 up to and including 0.5 micrometers, preferably 0.05 up to and including 0.3 micrometers, wherein, with a layer thickness of 0.25 μm, the silver tungsten alloy deposited using the electroless technique has a comparable wear-through resistance to a comparable pure silver layer with a layer thickness of 3.0 micrometers.
Alternatively, the contact element can be provided with a silver or silver alloy coating. The thickness of the deposited silver or silver alloy coating, including the carbon nanoparticles, is 0.05 up to and including 7.0 micrometers, but preferably 0.1 up to and including 3.0 micrometers.
An exemplary embodiment of the invention is illustrated in the drawings and will be explained in more detail below.
The figures contain partially simplified, schematic illustrations. Identical reference sign are sometimes used for elements which are similar, but possibly not identical. Different views of similar elements may be drawn to different scales.
The HARTING Technology group has made product catalogs and datasheets of all current products and their components available on the internet in the so-called download center (http://www.harting.com/DE/de/downloadcenter). In the following figures, contact elements are shown which can be produced, for example, with the above-mentioned materials, in particular with the aid of the machining technology. However, the geometrical diversity of the contact elements which can be produced with the said materials is not restricted.
The connector housing 10 consists of a base body 100, which forms a mating side and a cable outlet side. On the mating side, the contact elements (not shown) form the mating face of the connector. The contact elements can be pin contacts or socket contacts, which are produced according to the method presented above, for example.
On the cable outlet side, the base body 100 has an external thread 110 via which a cable gland with integrated strain relief can be screwed on.
The locking element 200 is pushed onto a cylindrical elongation of the base body 100 on the mating side. At the end, an external thread 210 is provided, via which the connector housing 10 can be connected to a mating connector and/or a device socket.
Even where combinations of various aspects or features of the invention are shown in the figures in each case, it is clear to a person skilled in the art—unless indicated otherwise—that the combinations shown and discussed are not the only possible combinations. In particular, mutually corresponding units or feature complexes from different exemplary embodiments can be interchanged with one another.
Number | Date | Country | Kind |
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20 2018 104 958.5 | Aug 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/DE2019/100738 | 8/16/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/043231 | 3/5/2020 | WO | A |
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