HU213964B - Electric connecting assembly, as well as arrangement having the electric connecting assembly and a filter assembly - Google Patents

Abstract

An electrical connector assembly (10) includes at least one signal contact (22) and one grounding structure (16) mounted in a dielectric housing (12) having flat exterior surface portions (19). A filter (32) is associated with each signal contact, if desired, and is in tape form with dielectric material (36) laminated between broad area electrodes (34,38) with the tape attached to the housing exterior surface (14); the dielectric material is selected to have a dielectric constant and thickness to provide a desired capacitance between signal and ground electrodes (34,38). The method includes electrically joining the signal and ground electrodes to the signal contact (22) and grounding structure (16) while pressing the tape filter along and against the exterior housing surfaces (19) between the connections, for the electrodes (34,38) of the filter to be connected between the signal contact and ground structure to effectively insert the filter in the signal path to ground. <IMAGE>

Description

The invention further relates to an arrangement comprising a filter element (32, 32 ') and a coupling assembly (10) having a dielectric, preferably plastic housing (14), a first and second interface mounting surface (25; 29) and at least one a contact (22,24) having a first and a second contact region, which are connected to the first and second mounting surfaces (25, 29) to provide a signaling circuit, the contact areas being arranged to transmit signals between the electrical wires; The assembly (10) further comprises an earthing shield (16), at least a portion of which is preferably disposed on the outer surface of a plastic housing (14) away from the first mounting surface (25), the arrangement itself being formed with exterior surfaces of known arrangement.

The arrangement consists in that a filter element (32, 32 ') is provided on the signal contact (22, 24) having at least one electrode (34, 34') for connection to at least one signal transmission circuit and at least one earth electrode (16) for earthing. 38

38 ') is provided between the electrodes (34, 38 and 34', 38 ') of the filter element (32, 32'), and is a dielectric layer formed by transmitting undesired frequency signals to the earth shield (16) being flexibly bent to any shape of the filter element (32, 32 ') between the first mounting surface and the second mounting surface (29) of the connector assembly (10) and at least partially adapted to the shielding element (16); 22, 24), near the first part of the element (32), the filter element (32, 32 ') is pressed against the outer surface of the plastic housing (14) at the hot tip (26, 28') of the contact (22, 24); (38, 38 ') proximate to the second portion of the filter element (32, 32'), away from the first portion, the top panel of the screen member (16) connected (17), extending along the outer surface of the filter element (32, 32 ') and geometrically conforming thereto without substantially altering the total volume of the connector assembly (10) and filling it with a minimum volume.

The present invention relates to an electrical connector assembly and an arrangement comprising an electrical connector assembly and a filter element, wherein the filter element is preferably a strip filter. The strip filter itself can be made of strip or ply and can be mounted on the outer surface of the connector housing or on a portion thereof.

The increasing use of high-speed digital pulse transmission for communication purposes has resulted in the use of highly sensitive components to properly receive and process these signals. However, this sensitivity made the components 35 more sensitive to the transmission of unwanted frequencies in the same transmission path as the frequencies to be transmitted.

To solve this problem, a number of solutions and improvements have been experimented with, all of which have been designed to provide electrical connectors that eliminate these unwanted frequencies. In any case, these filters must have the appropriate characteristics. U.S. Patent No. 4,695,115. The patent describes a telephone connector provided with a bypass capacitor and teaches that the capacitor incorporated in the connector is intended to filter out unwanted frequencies from the signals transmitted at the signal transmission terminal of the connector. These filters are formed by capacitors 50 which are designed to provide an appropriate capacity between the signal path and ground. However, these filters are relatively large in volume and, as a result, significantly increase the overall volume of the connector. 55

U.S. Patent No. 4,772,224. U.S. Pat. No. 4,102,125 discloses a modular electrical connector comprising capacitors and inductive coils which are generally ferrite-core and form a filter circuit with the capacitors. Similarly, U.S. Pat

No. 4,695,115 for this solution, the filter elements also occupy a very large volume, especially as regards their height, so that when placed on the printed circuit, the height of the printed circuit will be very high, and the connector with the filter will be very high. . It is an object of the present invention to provide a connector assembly and an assembly comprising a connector assembly and a filter element comprising a filter that does not substantially increase the volume occupied by the connector and requires only minimal space. It is also an object of the present invention to provide an electrical connector having a plurality of connector plugs provided with a thin strip filter on its outer surface, preferably on the connector housing, so that it is not damaged during the connector housing. The filter arranged in accordance with the invention may be formed in the shape of a connector fitting to the outer surface of the connector and may be passed through the apertures therein without further ado. It is also an object of the present invention to provide a 45-like, easy-to-mount filter edge arrangement which can also be used for connectors and other electrical elements such as printed circuits or data transmission cables.

The filter arrangement used in the present invention comprises one or more thin films forming the signal electrodes and one or more earthing electrodes between which a cover made of a thin dielectric material is disposed as a cover for the electrodes.

The present invention relates to an electrical connector assembly comprising a housing made of a dielectric material, preferably plastic, having electrical contacts fixed to the plastic housing, the connector assembly having hot tips extending from a first mounting surface, and a filter2.

GB 213 964 Β is electrically connected to at least one of the hot spots.

SUMMARY OF THE INVENTION The filter element comprises electrodes separated by a dielectric layer, one electrode electrically connected to one of the hot tips and the filter element itself extending along at least a portion of the outer surface of the plastic housing and electrically connected to the shield member of the connector assembly.

The filter element is electrically coupled to the hot tip and also has a grounding projection which is electrically connected to the sleeve.

The dielectric constant of the layer between the electrodes is selected so that the capacitance formed by the filter effectively filters out unwanted signal components, while ensuring that components of the desired frequency pass through the signal line and circuit. The undesired frequency components are substantially grounded through the filter. The filter itself contains the electrodes and the dielectric material arranged in layers, or a thin dielectric film is used to serve as a support for the electrodes, and the dielectric material is formed during manufacture and use. out like the outer casing of the connector.

The invention further relates to an arrangement comprising a filter element and a coupling assembly, wherein the coupling assembly has a dielectric, preferably plastic, housing, a first and second interface mounting surface, and at least one contact formed with first and second contact regions. are connected to the interface surfaces by means of a signaling circuit, the contact areas are arranged to transmit signals between the electrical wires, the connector assembly further comprises a grounding shield element, at least a portion of which is conveniently located on the outer surface of the plastic housing with exterior surfaces of known arrangement.

The essence of the arrangement is that each filter contact is provided with a filter element having at least one signaling circuit electrode and at least one earthing electrode connected to a grounding shield, between the filter element electrodes with an undesired frequency of the signal transmission components. a dielectric layer having a transmission characteristic to the shield member, which is flexible to form any shape of the filter element, resiliently and substantially in two-dimensional shape, and at least partially fitting the filter member to the surfaces of the connector assembly; of the filter element, preferably against the outer surface of a plastic housing, the grounding electrode is located near the second portion of the filter member, connected to the upper face of the sleeve member, extending along the outer surface of the connector assembly and geometrically conforming to the outer surface without substantially altering the total volume of the connector assembly; formed on its filler.

The signals that are led to the layout are routed through the printed circuitry through the signal contacts and the printed circuit layout, and thus the components of the arrangement can now use these signals for data transmission. Such a circuit board or a circuit arrangement associated therewith is disclosed, for example, in U.S. Pat. No. 07 / 971,028. filed November 3, 1992.

When used with a suitable connector, such as a telephone connector provided with a connector plug, both the signal and the earth electrode of the filter are provided with apertures through which the connector contacts can be fitted or subsequently soldered, that the laminated filter element is folded back from the bottom of the connector housing and then partially folded at the top of the connector housing to connect the grounding electrode to the shield and thereby ground the connector. Above the portions of the electrodes, an insulating layer is formed, except for the soldering sites, for example, by spray coating the polymer or by applying a polymer film.

The present invention can be used for quite different connectors, including connectors having at least one signal contact and at least one grounding contact, using different ribbon-like structures for the different signal contacts, depending on the size of capacity required, or we use a common ground and use separate electrodes for the signal contacts. In the present invention, the layering is configured to have a common grounding electrode having separated signal electrodes corresponding to the filtering capacities. As stated above, the filter of the present invention may be ribbon-like or laminated, but in any case provided that it is sufficiently thin and flexible, foldable and impressed on, for example, the outer flat surface of a connector housing, it may be secured by another fastener so that the filter is retained in the connector housing in the given position and the filter connector assembly can be treated as a single element. The filter-forming tape can also be mechanically secured to the connector housing by soldering, where it is secured to the signal connector and to the earthing connector, and is preferably secured to the plastic housing even after soldering. In this way, the volume increase due to the placement of the filter will be minimal and the filter element of the invention itself can be used with existing connectors and can be easily fitted.

HU 213 964 Β

The filter element of the present invention may also be used in conjunction with other electrical components, such as printed circuit boards, wherein the signal electrode and the grounding electrode may be directly soldered to the terminals of the signal or grounding conductors on the printed circuit board. The filter element itself can also be arranged so that it is positioned around the length of a shielded data cable.

The invention will now be described in more detail by way of exemplary embodiments in the accompanying drawings. The

Figure 1 shows an embodiment of a connector assembly according to the invention, wherein the connector is located above two filter elements formed according to the invention,

Figure 2 shows the elements shown in Figure 1 in partially assembled condition, a

Figure 3 is a partially sectional side view of the end of the filter connected to one of the contacts of the connector,

Figure 4 is a schematic drawing showing the end of the filter and its connection to the grounding circuit of the connector,

Fig. 5 is a plan view showing the end of the filter element and its connection to the ground of the connector assembly,

Figure 6 is a slightly enlarged view of the connector and filter shown in Figure 1, a

Figure 7 is a side view of the connector and filter immediately prior to assembly, a

Figure 8 is a side view of the embodiment shown in Figure 4, a

Figure 9 illustrates a further embodiment of a filter of the present invention comprising a pair of signal electrodes.

Referring now to Figure 1, an electrical component, here in an exemplary embodiment, an electrical connector assembly 10, comprises a connector 12, a pair of filters 32 and 32, each of which is shown in Figure 1 prior to assembly. The connector 12 may be, for example, a modular telephone connector which can be integrated into printed circuits and has a mounting surface 25 as an interface. Various telephone cables can be connected to this connector assembly 10, whereby the signals on the cable and connector assembly 10 can be transmitted to a printed circuit such as a telephone receiver, fax machine and / or other computer. The signal transmitted to the various connectors, consisting essentially of a pair of sockets, also transmits to the receiver circuit undesired frequencies which consist of leaks from the outside, radiation, induction, or other circuits through the cable. These unwanted frequency signals may represent an error signal, especially in digital signal transmission where digital one and zero signals must be transmitted.

The filter elements 32 and 32 'of the present invention are intended to filter out these unwanted frequency signal components so that useful signals can be properly transmitted, i.e., the appropriate voltage levels pass through the connector and pass to the receiver.

The configuration of the coupling assembly 10 shown in FIG. 1 is well known, comprising a coupling member 12, a plastic housing 14 having a grounding sleeve 16 on one side, and hot springs 18, 26, 28 on the underside of the connector. The embodiments shown in Figures 1 and 2 clearly show how they can be inserted and soldered into the respective openings on a printed circuit board. The plastic housing 14 is also provided with a plurality of grooves 20 which extend from the top of the connector 12 and extend downwards. The grooves 20 include the contacts 22 and 24 offset relative to one another and terminating at the terminals 28 and 26 when terminated. The soldering tips 26 and 28 are disposed below, positioned below, the first adapter mounting surface 25 and fit into the printed circuit board by contacting its respective printed wire. The second mounting surface 29 is provided with a shield 16 which terminates in an earthing pin 18.

The front portions of the contacts 22 and 24, not shown, are formed in a plug receptacle located at the second mounting surface 29 and receive the contacts connected to the cable. The plastic housing 14 also includes an elastic fastener 30 extending at the bottom of the plastic housing 14 or from the first mounting surface 25, which fits into a corresponding slot in the printed circuit board for receiving the connector 12. The elastic fastener 30 is illustrated in more detail in FIGS. . The resilient fastener 30 has an inner portion having a hook flange 31 which properly grips and locks the connector 12 on the printed circuit board before soldering the hot tips 18, 26 and 28 to the wires of the printed circuit board.

The earthing shield 16 is formed with side panels 15 facing each other and an upper panel 17 covering them, as shown in Figures 1, 2, 4 and 4.

5, and FIGS. 4, 5 and 8 also show how the top panel 17 is folded down. Of course, different embodiments may be provided, depending on the upper, lateral, front and lower side walls of the connector 12.

Generally, the top panel 17 and the side panels 15 have a relatively flat surface, while the front panel also includes flat surface portions, but here various protrusions and grooves can be provided. The connector assembly 10 according to the invention comprises two six contacts 22, 24 as signal contacts, each provided with two filter elements 32 and 32.

Of course, each of the six contacts 22 and 24 may optionally be provided with filter elements 32 and 32 ', as will be described below. Figure 1 shows that the filter element 32 comprises an upper electrode 34 and a lower electrode 38. These upper 34 electr

A dielectric layer 36 is disposed between the rode and lower electrode 38 (see Figure 3). At the front of the filter element 32, the upper electrode 34 is provided with a projection 35 having an aperture 37 adapted to receive the soldering tip 28 and thereby guiding the soldering tip 28 at the soldering position S to the edges of the aperture 37. This is shown in more detail in Figure 3. At the rear of the filter element 32, a grounding projection 39 is formed in the lower electrode 38, which provides a proper grounding connection. This is also soldered to the bottom shield. The signal transducers 26 and 28 are spaced apart, and the top 17 of the grounding shield 16 forms a grounding connection sufficiently distant from the signal component connections. The projection 35 is laterally electrically separated from the filter element 32 in some way, allowing it to be properly spaced from the tip 26 so that the tip 26 is connected to the upper electrode 34, through the opening 37 '. The filter element 32 'is also provided with a grounding projection 39'.

Each of the filter elements 32, 32 'comprises an upper electrode 34 or 34' and a lower electrode 38 or 38 'separated by a dielectric layer 36. This arrangement may be formed by first forming layers of suitable conductive material on the respective surfaces of the sheets of dielectric material, followed by etching to form the corresponding outer surface of the electrodes 34 and 38, and in the course of such etching, many a belt filter can be formed. Preferably, the outward facing surfaces of the electrodes 34 and 38 are, after etching, covered by the insulating layers 134 and 138 shown in FIG. The insulating layers 134 and 138 may be, for example, a polymeric paint that can be spray-applied or, with the exception of the soldering points of the electrodes, coated with a polymeric film layer. The electrodes 34 and 34 are connected to each of the contacts 22 and 24 by and electrodes 34 'have portions provided with a dielectric layer 36 having a corresponding dielectric constant and thickness so as to provide sufficient capacity for each of the contacts 22 and 24 and to ensure that each of the contacts 22 and 24 through the capacitance, they can be coupled to the ground or common earth electrode 38. As is well known, a capacitance depends on the surface area of the electrodes 34 and 38, the dielectric constant of the dielectric layer 36 therebetween, and the capacity decreases as the distance between the electrodes 34 and 38 increases, and as the dielectric constant increases.

In one embodiment of the invention, the electrodes 34 and 38 are formed of a film having a film thickness of about 3.5 x 10 &^lt; ⁵ &gt; Thus, 5 * 10 ^-5 m results in a filter element 32 having a thickness of 1, 2 * 10 ^-4 m. The polymer film may be, for example, an RHEOPLEX LC 40 acrylic adhesive emulsion manufactured by Rohm and Haas, Inc., consisting of an acrylic polymer matrix in which barium titanium filler is homogeneously dispersed, e.g. 50% by weight. The particles have a diameter of approx. 10 ' ^6s This film can be used as a dielectric layer, for example. The conductive layer is made of high-purity copper applied to the dielectric layer 36 by a technology that first uses a heat and pressure layering machine.

With this layering, a capacitance of 400 to 480 pF was achieved, each individual electrode 34 and 38 having a width of 5 * 10 'and a length of 2.5 * 10 ~ ² m. The resulting capacity allowed the insertion damping to be a few dB below 10 MHz, 12-15 dB at 100 MHz, and ca. At 250 MHz, approx. 34 dB. The 480 pF capacitance loss was less than 30 dB around 200-300 MHz. The use of an appropriate amount of barium titanium in the polymer allows the capacitance to withstand a voltage of 1000 V or greater, which is required by certain FCC regulations.

Optionally, opposed anodized aluminum foil, which is deposited on a barrier titanium filled polymeric layer, or barium titanium charged polymeric particles are printed or spray-coated, and an additional layer is applied thereto. Suitable geometric shapes may also be formed, the film layers may be etched in a manner known per se as the electrode structure is etched, followed by the application of a 350C epoxy coating as the insulating layers 134 and 138 to the outer surfaces of one or both electrodes 34 and 38. The filter elements 32 thus formed are strip filters which can be simply cut off.

The filter elements 32 and 32 'are sandwiched with an insulating dielectric layer 36 between the electrode 38 and the electrode 34, and each electrode 34 and 34' is provided for the contacts 22 and 24 respectively. 28 soldered using soldering tips. The layer arrangement formed by the filter elements 32 and 32 'is folded down over the plastic housing 14 of the connection element 10 and lies on the flat surfaces thereof as shown in FIG. 7, but also in FIGS. 1 and 2 covering the grooves 20. and is located between the protruding flanges 41 of the connector 12. This serves to protect the side edges and to prevent the filter element 32 from being placed in such a position that the soldered joints are subjected to high mechanical stress. The shape and size of the filter elements 32 and 32 'are selected such that the projections 35 and 35' are offset relative to one another and located near the respective source tips 26 and 28, respectively. Grounding is accomplished by projections 39 and 39 'which are also offset relative to one another and located near the top panel 17 of the grounding shield 16.

When the ends of the filter elements 32 and 32 'are folded down along the top panel 17, then this top panel 17 is folded down over the projections 39 and 39', as shown in FIG. 8, and FIG. soldering

The location 39 connects the projection 39 of the electrode 38 to the top plate 17, likewise the grounding shield 16 and the soldering point S 'connect the projection 39' to the electrode 38 of the filter element 32 'and are both connected to the same ground. The two filter elements 32 and 32 'can be folded back and connected to the grounding arrangement as shown. Optionally, after soldering, it may be necessary to pour an outer layer on the strip forming the filter element 32 for protection, or to cover the connector 12 with a pre-melted plastic at its portion with the filter element 32, thereby protecting the filter elements 32.

The arrangement according to the invention may also be designed so that the filter element 32 is individually grounded and not connected to a common ground point. The projections 39 and 39 'can be used for this purpose. The arrangement according to the invention may also be formed by enlarging the surface of the electrode 34 near a specific contact 22 where necessary, and placing additional elements on the other signal contacts 24. This accessory can be, for example, the electrode 40 shown in Figure 8, which is indicated by a dashed line, which represents an increased capacity for the entire filter arrangement.

The connector assembly of the present invention may also be configured to have a signal terminal 22 and a grounding terminal, or may have two, four, or six terminals 22. FIG. 9 shows an embodiment comprising a filter element 80, which filters the filter element 80 in a strip-like arrangement, filtering two contacts. The filter element 80 comprises two signals 82 and 84, which are disposed on the same side of the dielectric layer 36 and are separated by a gap 86. A single grounding electrode 88 is provided with the system, which is disposed on the other side of the dielectric layer 36. Each of the electrodes 82 and 84 includes projections 90 and 92, respectively, which pass through the axis of the respective signal outlets, and through the apertures 94 and 96, the projections 90 and 92 can be soldered to the source tips 26 and 28, respectively. The grounding electrode 88 also includes one or two projections 98 shown in the drawing which extend beyond the electrodes 84 and 82 and can be soldered to the sleeve 16 of the connector 12. The present invention can be used in a variety of configurations, where it can cover different portions of the outer surface of the connector housings, the essential being to have the surface required for a given capacity.

Claims (8)

PATENT CLAIMS An electrical connector assembly comprising a dielectric material, preferably a plastic housing (14), on which electrical contacts (22,24) are fixed to the plastic housing (14), attached to the connector assembly (10) as a continuation of the contacts (22,24). hot tips (26, 28) disposed extending from an adapter first mounting surface (25), and a filter element (32, 32 ') electrically connected to at least one of the hot tips (26, 28), characterized in that the filter element (32, 32 ') comprising electrodes (34, 38 and 34', 38 ') separated by a dielectric layer (36), one electrode (34, 34') being electrically connected to one of the hot tips (26, 28), the filter element (32) 32 ') is preferably extending along at least a portion of the outer surface of the plastic housing (14) and electrically (38, 38') of the other electrode to a grounding shield element (10) of the connector assembly (10). 16) is connected. Electrical connector assembly according to claim 1, characterized in that the filter element (32, 32 ') is provided with an electrically connecting projection (35, 35') to the hot tip (26,28). Connector assembly according to claim 1 or 2, characterized in that the filter element (32,32 ') is also provided with a grounding projection (39,39') which is electrically connected to the shielding element (16). 4. Electrical connector assembly according to any one of claims 1 to 3, characterized in that the sleeve (16) is provided with an upper plate (17) which is folded down, which is preferably mounted on a plastic housing (14). 5. 1-4. Electrical connector assembly according to any one of claims 1 to 3, characterized in that the backsheet and top panel (17) of the plastic housing (14) are substantially flat and the filter element (32, 32 ') is connected to the plastic housing (14) along these flat surfaces. . An arrangement comprising a filter element (32, 32 ') and a connector assembly (10) comprising a dielectric, preferably plastic housing (14), first and second mounting surfaces (25, 29) of the connector assembly (10), and at least one a contact (22, 24) formed by first and second contact regions, which are connected to the first and second mounting surfaces (25, 29) to provide a signal transmission circuit, the contact areas being arranged to transmit the signal between the electrical wires, (10) further comprises a grounding sleeve (16), at least a portion of which is disposed on the outer surface of the preferably plastic housing (14) away from the first fitting mounting surface (25), the arrangement itself being formed with exterior surfaces of known arrangement, that one o for each signal contact (22, 24) a filter element (32, 32 ') having at least one electrode (34,34') which can be connected to a signal transmission circuit and at least one earth electrode (38, 38 ') that can be connected to a grounding shield (16); '), between its electrodes (34,38 and 34', 38 '), there is a dielectric layer (36) formed by the characteristic of transmitting unwanted frequency signals to the grounding shield (16), the filter element (32, 32') itself. being flexibly deformable in any shape to form a substantially dimensional shape between the first mounting surface (25) and the second mounting surface (29) of the coupling assembly (10) and at least partially adapted to the shield (16), the signal contact (22,24) (32, 32 ') in the vicinity of the first portion of the given tangent At the hot tip (26, 28) of the contact (22, 24) for the contact (22, 24), the filter element (32, 32 ') is pressed against the outer surface of the plastic housing (14), the earth electrode (38, 38') 32, 32 ') proximate to the second portion 32, 32') connected to the top panel 17 of the sleeve member 16, the filter member 32, 32 'extending along the outer surface of the connector assembly 10 and geometrically conforming thereto on the outer surface without substantially altering the total volume of the coupling assembly (10) and when filling a minimum volume. Arrangement according to claim 6, characterized in that the connection points are formed by soldering. Arrangement according to Claim 6 or 7, characterized in that these earthing projections (39, 39 ') are folded back into the housing after being connected to the earthing electrode (38).