The present disclosure relates to the field of connectors, in particular to the field of shielding arrangements for connectors, more in particular to a shielding shell for a connector.
BACKGROUND Connectors for connecting one or more signals may require shielding against electromagnetic noise generated or received by carriers along which the signals are transmitted. Such shielding may efficiently be provided in the form of a shielding shell comprising conducting material which covers at least a portion of the connector.
When designing and manufacturing such a shielding shell and a connector comprising such shell, a compromise has to be found between shielding efficiency, material consumption and manufacturing ease. Manufacturing a shield by folding a sheet of material, e.g. a metal sheet, about (a portion of) a connector terminal housing has proven a useful technique for providing a shielding shell. However, the technique of folding may generally provide limited accuracy, which may require significant effort and cost for meeting manufacturing tolerances and providing adequate shielding.
With the ongoing trend of miniaturization and increasing signal speed the aforementioned problems become more acute.
Consequently, there is a demand for an improved shielding shell addressing these problems.
In one aspect, a shielding shell according to claim 1 is provided. The first, second and third walls of the shielding shell allow covering a connector body of a connector at least partially. The first folded edge facilitates manufacturing. It also allows adapting the angle between the first and second walls to fit a connector body to be shielded. The first contact portion allows providing proper contact between the second and third walls. This improves the shielding efficiency of the shielding shell. The plurality of contact segments ensures a plurality of contact points between the second and third walls. The separation between contact points defines a maximum wavelength of EMI radiation which may inadvertently escape through a space between the contact points, which translates into a minimum frequency of such escaping signal. By providing a plurality of contact points the minimum escape frequency can be determined so as to define a frequency range which is not experienced or considered as noise to and/or which is substantially absent from signals to which the connector is (configured to be) exposed. Providing a shielding shell with a plurality of contact segments instead of a single segment thus provides an improved shielding. It further facilitates manufacturing since the individual segments may adapt or be adapted to contact portions of the third wall with different tolerances, e.g. a somewhat inaccurate relative position and/or angle between the first, second and/or third walls. Thus, proper contacting between the third wall and the contact segments may be ensured. As a consequence folding tolerances may slacken whereas a proper shielding may still be ensured. The efficiency and reliability of the shielding shell may be further enhanced by providing one or more of the contact segments with a resilient portion, allowing the considered contact segment to exhibit a spring finger action.
The shielding shell of claim 2 allows an end edge of the third wall to be hidden behind the first, substantially continuous, portion and thus allows preventing apertures in the shielding shell. This reduces chances of leaking radiation through the slots and thus improves the shielding efficiency of the shielding shell.
The shielding shell of claim 3 allows providing the first, second and third walls as a substantially unitary shielding shell, which may facilitate manufacturing of the shielding shell. It may also substantially prevent gaps from occurring between the first wall and the third wall. Thus, the shielding efficiency is further improved.
The shielding shell according to claim 4 and/or 5 facilitates folding the shielding shell into a desired shape. The first and/or second leading edge portions may be shaped in various ways, e.g. by a beveled edge or by a portion of the edge being bent out of a main plane or direction in which the particular wall or contact portion extends. Preferably, the first and/or second leading edge portions are arranged for being the point or zone subject to a first contact between the first contact portion and the third wall during folding of the first and second walls along the first folded edge.
The shielding shell of claim 6 allows forming the second leading edge portions, e.g. by deflection out of a plane in which the third wall extends, whereas one or more other portions of the third wall are unaffected by the presence of the second leading edge portions. Examples are a folded edge, a portion comprising one or more contact terminals and/or a portion configured for abutting a portion of a further object such as a connector body. This facilitates manufacturing of the shielding shell, and allows adhering to tolerances of the one or more other portions.
The shielding shell may comprise one or more further walls for further enveloping a connector body. The shielding shell of claim 7 is particularly suitable for an angle connector, e.g. a right angle connector or a 45 degree connector.
The shielding shell of claim 8 facilitates optimizing usage of space in a device in which the shielding shell is to be used. It may in particular be used for substantially right-angled connectors.
Further aspects of the invention are defined in claims 9 and 10. A connector may be provided with the shielding shell, as defined in claims 11 and 12.
A shielding shell according to the above description may suitably be manufactured by forming the blank defined in claim 13 and folding the blank. The blank may be made with or from sheet material, e.g. a metal sheet, and may be formed by cutting, stamping or other suitable ways.
The invention will hereafter be more fully explained with reference to the drawings, showing an embodiment of the invention by way of example.
The shown connector 1 is a right-angle connector which is configured for being mounted to a further object, in particular a circuit board (not shown). The shielding shell 3 comprises a first wall 4 on its top side, a second wall 5 on its rear side, third and fourth walls 6 and 7, respectively, on substantially opposite sides and further wall portions 8 on its bottom side. The shielding shell 3 is fitted to the connector body 2, primarily by interaction between the wall portions 8 and further portions protruding from them, which are received in the connector body 2. Thus the connector body 2 and the shielding shell 3 are fixed together.
The used references to top, rear, side and bottom, etc, are relative to the connector 1 as shown in the drawings and for purposes of facilitating the further description and should not be construed as limiting the scope of the present disclosure.
The shown shielding shell 3 is a substantially unitary object manufactured by folding an appropriately formed blank. Thus, the first wall 4 and the second wall 5 are connected to each other by a first folded edge 9, the first wall 4 and the third wall 6 are connected to each other by a folded edge 10 and the first wall 4 and the fourth wall 7 are connected to each other by a folded edge 11. The further wall portions 8 are likewise connected to the third and fourth walls 6, 7 by further folded edges. In the shown shielding shell 3 each wall 4-7 and wall portion 8 is arranged at a mutually substantially perpendicular angle to each adjacent wall (portion) 4-8, although other angles may be envisioned. Contact legs 12 protrude from the third and fourth walls 6, 7 for contacting the shielding shell to further structures such as one or more ground contacts on a further object, e.g. a circuit board.
The shown shielding shell 3 comprises a plurality of contact springs, generally indicated with reference numeral 13, which are arranged at various locations on the walls 4-8 for contacting further objects such as wall portions of a device, e.g. edges of a port opening of a front panel into which the connector is received. This may provide and/or improve contact between the shielding shell 3 and different portions of the object, and therewith interconnecting the different portions of the object themselves, preventing build-up of potential differences between the shielding shell and (portions of) the object. This improves shielding efficiency of the assembly of connector 1 and the object and may further protect connected electronics against static discharge. The contact springs 13 may also generally improve fixation of the shielding shell 3 and thus of connector 1 to the object.
The shielding shell 3 further comprises a first contact portion 14 extending from the second wall 5 and connected with it by a folded edge 15 and a second contact portion 16 extending from the second wall 5 connected with it by a folded edge 17. The first contact portion 14 is arranged substantially parallel to the third wall 6. The second contact portion 16 is arranged substantially opposite the first contact portion 14 with respect to the second wall 5 and it is substantially parallel to the fourth wall 7. The first and second contact portions 14, 16 each comprise a plurality of contact segments 19, each of which engaging the third and fourth walls 6, 7, respectively, making electrical contact thereto. One or more contact segments 19 preferably comprise a resilient portion for improving the contact pressure between the contact segment 19 and the appropriate wall 6, 7. The contact segments 19 are separated by slots 20 which extend from a far end of the contact portion 14, 15, relative to the folded edges 15, 17, towards but not all the way up to the folded edge 15, 17. Thus each contact portion 14, comprises a first portion 21 which is substantially continuous along and adjacent the folded edge 15, 17, respectively, in addition to a second portion comprising the contact segments 19 and the slots 20.
The length of the slots 20, and thus the width of the first portion 21 of the contact portions 14, 16 are configured such that the first portion 21 masks an edge of the third wall 6 or fourth wall 7 substantially preventing apertures through the shielding shell between third wall 6 and/or fourth wall 7 and the contact portion 14, 16.
As may be most clearly seen in FIGS. 1B and 3A-3E, the (contact segments 19 of the) first and second contact portions 14, 16 comprise a first leading edge portion 22 arranged towards the far end of the contact portions 14, 16, relative to the folded edges 15, 17, which deflects with respect to a main plane in which the corresponding contact portion 14, 16 substantially extends.
In a following folding step the first and second walls 4, 5 are folded along the folding edge 9 to finish forming the shielding shell (see arrows in
The first and second leading edge portions 22, 27 are arranged for being the portion(s) subject to the first contact between the third wall 6 or fourth wall 7 and the corresponding contact portion 14, 15, with respect to the folding direction about the first edge 9. In the shown embodiment such first contact is established at a folding angle α of about 45 degrees from the unfolded situation between the first and second walls 4, 5 (
The combination of the first and second leading edges 22, 27 allows maintaining a guiding efficiency during the folding step of the engaging walls.
The actual folding angle α at which first contact is established between a contact portion and the according wall depends on the actual shape of the considered wall edge portion and the contact portion. The optimum position of a first wall segment and a further wall segment may therefore be different from the shown embodiment.
The finished shielding shell 3 may then be mounted to or assembled with the connector body 2 to provide a shielded connector 1. Alternatively, one or more folding steps for forming the shielding shell 3 may be performed directly around the connector body 2.
In the finished shielding shell 3 (
The invention is not restricted to the above described embodiments which can be varied in a number of ways within the scope of the claims. For instance the first and/or second contact portion may be arranged at an inside of the shielding shell, opposite to the shown embodiments.
The shielding shell may have more walls and corresponding contact portions arranged according to the disclosure. Different contact portions may have mutually different orientations and/or shapes and sizes.
Wall portions 8 may be shaped differently or be absent, e.g. in accordance with another function and/or another attachment method between the shielding shell and the connector body.
Further, the shielding shell may comprise more, less and/or differently arranged contact legs 12, e.g. extending from the rear side (second wall 5) or bottom side (wall portions 8) of the shielding shell.
Elements and aspects discussed in relation with a particular embodiment may be suitably combined with other embodiments.
Number | Date | Country | Kind |
---|---|---|---|
PCT/IB2009/053461 | Mar 2009 | IB | international |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2010/054089 | 3/29/2010 | WO | 00 | 2/13/2012 |