FR2606207A1 - Electronic filtering unit with separate capacitive elements - Google Patents

Abstract

The invention relates to an electronic filtering unit with capacitive elements. The unit comprises an electrically conducting plate 1 and a plurality of separate capacitive elements denoted Ei. Each element has a through hole denoted Oi forming first connection terminal Bi1 of the capacitive element Ei and is mounted in a mounting orifice denoted ORi of the plate 1. The second connection terminal Bi2 of each capacitive element Ei is electrically connected to the electrically conducting plate 1. Application to the filtering of the terminals of connectors, and to the construction of multiple feed-through filters.

Description

The present invention relates to
an electronic filtering unit with capa elements
discreet citives.

Currently, sets of
electronic filtering multicapacitors find
many applications, for example in the
field of electronic filtering of connectors.

In the case of electronic filtering, and in particular
in the case of using multiple filters,
multiple filters for connectors, adapters
filtering for connectors, two essential techniques
have been developed.

 A first technique consists in using individual monolayer tubular capacitors directly threaded on the pins of the connector. This first technique allows suitable filtering but involves a large increase in volume. of the components and of the fact that the capacitance values of these capacitors are low, makes it possible to have only high cut-off frequencies and therefore little filtering efficiency at EMI / RFI frequencies, the lowest.

 A second technique however has nervis to partially solve the problems posed by the previous technique. It consists in producing a multilayer and multicapacitive ceramic plate, the plate being pierced with a plurality of metallized orifices. Of course, each metallized orifice corresponds to the connection terminal of an elementary capacitor, the periphery of the metallized ceramic wafer being electrically connected to ground or reference potential in operation. Each connector pin threaded into a metallized orifice to which it is electrically connected, is then subjected to the desired filtering. A sectional view of such a multicapacitive ceramic plate of the prior art is shown in FIG. 1.

 This second technique, if it has certain advantages over the first such as reduction in size, ease of production and implementation of multiple cells, however has the drawbacks inherent in the fragility of the ceramic and the difference , inevitable, expansion coefficients of the ceramic with the surrounding metallic materials.

 In addition, as will be understood from the observation of FIG. 1, by the multilayer and multicapacity structure of the ceramic wafer, each elementary capacitor has substantially the same value of electrical capacity, which due to the technology used, can hardly exceed 100 nF for gauge contacts 20 with spacings of 3.3 mm. This therefore results in both a lack of flexibility of the filtering characteristics by terminal, as well as a license to cel1es- this.

 The object of the invention is to remedy the drawbacks of the first and second techniques known to date.

 Another object of the present invention is the implementation of an electronic filter assembly with discrete capacitive elements.

 Another object of the present invention is the implementation of an electronic filtering assembly with independent discrete capacitive elements, which may have different values of electrical capacity and / or operating voltage.

 Another object of the present invention is the implementation of an electronic filtering assembly of great robustness and having a high degree of reliability.

 Another object of the present invention is finally the implementation of an electronic filtering assembly capable of being used for filtering connectors whether or not these comprise rocks of different cross-section or diameter. The electronic filter assembly with capacitive elements which is the subject of the invention is remarkable in that it comprises an electrically conductive plate and a plurality of discrete capacitive elements. Each of these capacitive crossing elements has a through hole forming a first connection terminal of the capacitive element and is mounted in a mounting hole of the wafer. The second connection terminal of each capacitive element, peripheral terminal, is electrically connected to the metal support plate.

 The electronic filtering assembly with capacitive elements which is the subject of the invention finds application in all "multiple" filtering cases, for example multiple feed-through filters or filtering of multi-pin connectors.

A more detailed description of the electronic filtering assembly according to the invention will be given in relation to the drawings below in which, in addition to FIG. 1 relating to the prior art,
FIG. 2a represents a cutaway perspective view of an electronic filtering assembly which is the subject of the present invention,
FIG. 2b represents a perspective view cut away of a capacitive element constituted by a discoid capacitor constituting the electronic filtering assembly object of the present invention,
FIG. 3a represents a sectional view along a section AA of FIG. 2a of an electrically conductive plate constituting the electronic filtering assembly according to the invention, in the absence of the capacitive elements,
FIG. 3b represents an advantageous alternative embodiment of the electrically conductive plate shown in FIG. 3a,
FIGS. 3c and 3d show respectively a sectional view along a section AA of FIG. 2a, of the filtering assembly in the case where the electrically conductive plate used corresponds to that shown in FIG. 3a and 3b respectively,
- Figure 4 shows one of Ee face of an electronic filter assembly according to the object of the present invention more particularly suitable for use such as filtering the pins of a connector, a round connector.

 The invention will first be described in relation to FIG. 2a.

 In accordance with the aforementioned figure, the electronic filtering assembly with capacitive elements which is the subject of the invention comprises a plate denoted 1 electrically conductive. It also includes a plurality of discrete capacitive elements. In FIG. 2a, each discrete capacitive element is denoted Ei. Each of these elements has a through hole, denoted Oi, forming the first connection terminal S of the corresponding capacitive element Ei. Each element Ei is mounted in a mounting orifice denoted ORi of the electrically conductive plate 1. The second connection terminal of each capacitive element Ei is denoted Bi2 and is electrically connected to the electrically conductive plate 1.

As shown in Figure 2a, the mounting holes ORi of the capacitive elements
Ei are configured on the electrically conductive wafer 1 according to a determined pitch network.

 Of course, and in a nonlimiting manner, the electrically conductive plate 1 can consist of a metal plate made of an alloy which is a good conductor of electricity, as will be described later in the description.

 A particularly advantageous variant of the electronic filtering assembly which is the subject of the invention will now be described in conjunction with FIG. 2b.

 In accordance with the above figure, each capacitive element Ei. may consist of a disc capacitor, denoted 100, in FIG. 2b. Conventionally, these discoid capacitors have a peripheral metallization denoted 102, forming the second connection terminal of the capacitive element Ei, connection terminal which is electrically connected to the electrically conductive plate 1. They also have a central orifice forming a through hole , having a metallization denoted 101 and forming the first connection terminal of the capacitive element Ei. These discordant capacitors are ceramic dielectric capacitors, obtained by thin sheet casting.

The electrodes of the capacitor are obtained by sintering a metal chosen for its low affinity with the components of the ceramic. A number of slats are stacked and then agglomerated. This type of capacitor will not be described in more detail since it is normally commercially available and in particular described in the catalog of products of the Applicant.

 A more detailed description of the structure and of the assembly of the electronic filtering assembly which is the subject of the invention will be described in conjunction with FIGS. 3a, 3b, 3c, 3d.

 In Figure 3a, there is shown a sectional view along a section denoted AA of Figure 2a, of an electrically conductive plate 1 constituting the electronic wiring assembly object of the invention in the absence of the capacitive elements Ei .

As shown in Figure 3a, each mounting hole ORi of the wafer 1 can be constituted by a through hole.

In addition, according to another advantageous embodiment represented in FIG. 3b, by way of nonlimiting example, each mounting orifice ORi may comprise a shoulder denoted Epi then forming housing for the corresponding capacitive element Ei. The shoulder
Epi of each ORi mounting hole can be made by successive machining in the electrically conductive plate 1, for each ORi mounting hole, corresponding to two bores of different diameter.

 In Figures 3c and 3d, there is more particularly shown in section along a section AA of Figure 2a, an embodiment corresponding to the electronic filter element object of the invention, in the case where a metal plate 1 as shown in FIG. 3a, then respectively in FIG. 3b is used.

 In the case of the two embodiments given by way of nonlimiting example, represented in FIG. 3c and 3d, each of the discrete capacitive elements Ei is electrically connected in a suitable way marked 20, in the corresponding mounting ori.

 Of course, in order to eliminate any risk of mechanical deterioration of the electronic filtering assembly object of the invention as shown in FIG. 3c and 3d, the electrically conductive plate 1 is made of a material having a coefficient of relative linear expansion understood between 4 x 10 6 and 20 x 10 6 per OC.

TR material used can of course be a copper alloy, a bérvllium bronze, a -, - erro-nickel, a ferro-nickel with cobalt, the material or alloy Ge the electrically conductive plate 1 being naturally chosen to have a coefficient of expansion as close as possible to that of the ceramic or dielectric constituting the capacitive elements Ei so as to minimize the mechanical stresses during temperature variations.

 In addition, the mechanical stresses developed by the aforementioned possible temperature variations are advantageously reduced by the judicious choice of an efficient electric and mechanical connection which is knotted in FIGS. 3c and 3d, which then make it possible, owing to their suitable ductility, absorb the aforementioned stresses during large temperature variations.

 Tests of implementation of the electronic filtering assembly which is the subject of the invention were carried out in the case of assemblies more particularly adapted to the filtering of connector pins such as connectors of the Cannon type or round connectors with capacitors discoids with a diameter substantially equal to 2.5 mm. The tests carried out showed that the electrical characteristics of the capacitors used before and after mounting in the electronic filtering assembly which is the subject of the invention did not present any significant variation in value both from the point of view of the value of the electrical capacity of these capacitors as the tangent of the dielectric loss angle or the insulation resistance.

 Of course, according to an advantageous characteristic of the electronic filter assembly which is the subject of the invention, the capacitive elements Ei can have equal or different dielectric capacitance values. Such a possibility gives the electronic filter assembly according to the invention, a very great flexibility of use, in particular depending on the nature of the signals to be filtered at each connector pin for example and therefore the type of connector. .

 In addition, and according to another particularly advantageous characteristic of the electronic filter assembly which is the subject of the invention, the capacitive elements Ei can advantageously have equal or different operating voltages or nominal voltages. This new possibility further adds to the flexibility of use of the electronic filtering assembly which is the subject of the invention.

 In the same way, and in a nonlimiting manner, the capacitive elements Ei can be chosen so as to present a central orifice Oi of different or equal dimension making it possible to filter contacts of different gauge, this possibility of course adding still to the flexibility of use of the electronic filtering assembly, object of the invention.

As previously mentioned in this description, the filter assembly
electronics object of the invention can advantageously
be used to filter electrical or electronic connector pins.

In this case, the network of mounting holes ORi formed in the electrically conductive plate 1 and consequently through holes
forming the first connection terminal, that is to say the through holes Oi of each capacitive element Ei, is configured at the pitch of the network of connector pins.

In Figure 4, there is shown a
seems to electronic filtering in accordance with this
invention, in the case where it is more particularly intended for use for filtering a burp connector, model HE 303 15-1 "arrangement, marketed by various companies (standard UTE C 93-422-ADD 3 - Sheet 8 of 30.8.79), this connector comprising 1 9 pins.
As mentioned above, the electronic filter assembly which is the subject of the invention is in the form of a metal plate having 19 through holes.
Oi, arranged, as shown in Figure 4.

According to another particular characteristic
The advantageous advantage of the electronic filter assembly which is the subject of the invention, as it appears in particular in a nonlimiting manner in FIG. 4, the peripheral shape of the electrically conductive plate is configured and adapted to the internal shape of the connector body. thus, before or after installation of the assembly which is the subject of the invention by threading each pin of the connector into a respective central hole or through hole Oi, the plate is in electrical contact with the body of the connector forming reference potential. understood, the electrically conductive plate 1 can have and have any peripheral, discoldal, tectangular, trapezoidal shape or the like adapted to the configuration of the element to be filtered such as a connector.

 An electronic filtering assembly has thus been described in accordance with the object of the invention, which, compared with the devices of the prior art already known, has advantages such as a highly improved yield for manufacturing these elements, a very great flexibility of use due to the ease of implementation in the electronic filtering assembly object of the invention of a filtering point having values of electrical capacity and / or operating voltage or different nominal voltage, with in in addition to the dimensions of the through holes of each capacitive element also different if necessary, possibility of an easy possible replacement of a determined capacitive element failing, reduction of the mechanical stresses exerted on the dielectric element of each capacitive element Ei by the use of '' a material constituting the electrically conductive plate having a coefficient of expansion adapted to that of this dielectric material iced consisting of a ceramic, presence of electrically and mechanically suitable connections surrounding each capacitive element Ei and playing substantially the role, with respect to the aforementioned mechanical stresses of a damper of these stresses.

Claims (11)

 1. Electronic filtering assembly with capacitive elements, characterized in that it comprises:  - an electrically conductive plate (1),  - a plurality of discrete capacitive elements (Ei), each of said elements having a troutraversant (Oi) forming the first connection terminal (Bil) of the capacitive element (Ei), being mounted in a mounting orifice (ORi) of said plate (1), the second connection terminal (Bi2) of each capacitive element (Ei) being electrically connected to said electrically conductive plate.  2. Electronic filter assembly according to claim 1, characterized in that said mounting orifices of said capacitive elements are configured on the electrically conductive plate according to a network of determined pitch.  3. Electronic filter assembly according to one of claims 1 or 2, characterized in that each capacitive element (Ei) consists of a discoid capacitor (100) having a peripheral metallization (102) drilling the second connection terminal of said element capacitive electrically connected to said plate (1) and a central orifice, forming a through hole, having a metallization (101) and forming said first connection terminal of said capacitive element.  4. Electronic filtering assembly, according to one of claims 1 to 3, characterized in that each mounting orifice (ORi) of said wafer is constituted by a through hole.  5. Electronic filtering assembly according to the revendica (ion 4, characterized in that each mounting orifice (ORi) has a shoulder (Epi) forming a housing for said capacitive element.  6. Electronic filter assembly according to one of the preceding claims, characterized in that each of said discrete capacitive elements is mechanically and electrically connected (20) to the corresponding mounting orifice (ORi).  7. Electronic filter assembly, according to one of the preceding claims, characterized in that said electrically conductive plate is made of a material having a coefficient of relative linear expansion between 4 x 10 6 and 20 x 10-6 by "C .  8. Electronic filter assembly according to one of the preceding claims, characterized in that said capacitive elements (Ei) have equal or different electrical capacitance values.  9. Electronic filtering assembly according to one of the preceding claims, characterized in that said capacitive elements (Ei) have equal or different operating voltages.  10. Electronic filter assembly according to one of the preceding claims, characterized in that said capacitive elements (Ei) have a central orifice forming a through hole (Oi) of different diameter.  .11. Use of an electronic filtering assembly according to one of Claims 1 to 10, preceding the filtering of the pins of triec or electronic Slec connectors and of multiple crossing filters, FMr.  1 2. Use according to claim 10, characterized in that the network of mounting holes and through holes forming the first connection terminal is configured at the pitch of the network of connector pins or FMT.  13. Use according to claim 11 and 12, characterized in that the peripheral shape of said wafer is configured and adapted to the internal shape of the connector body or of the FMT, so that, after installation of said assembly and threading of the connector pins in their respective central hole, said plate is in electrical contact with the body of the connector or of the FMT forming reference potential.