RU49377U1 - ELECTRIC FILTER CONNECTOR - Google Patents

Abstract

The utility model relates to electrical engineering, in particular to installation products for connecting blocks and REA devices. The essence of the proposal is that in the electric connector-filter, which contains a metal cylindrical body, contact elements with filters, a dielectric with holes for contact elements and a ground plate, a shield made of radar absorbing material is installed between the dielectric and the ground plate in the form of a cylinder adjacent to its side surface to the inner wall of the housing. Contact elements in the upper part of the housing are filled with an insulating compound. The technical result of the utility model is to reduce signal reflection, increase resistance to strong magnetic fields, and increase noise immunity.

Description

The inventive utility model relates to the field of electrical engineering and can find application as an installation product for interconnecting various units and devices of electronic equipment.

Known multi-pin filter connector (Aut. St. USSR No. 1457028, IPC ⁷ H 01 R 13/66, publ. 02/07/89), containing a cylindrical body, in the cavity of which are installed rigid sealing sleeves, two capacitor blocks, contact elements in in the form of pins and ferrite inductive elements made in the form of a single block with holes made of ferrite with a relative magnetic permeability μ≤600.

The disadvantages of this device include a high reflection coefficient of interference, low immunity to strong magnetic fields, the complexity of the design and manufacturing technology.

Also known is an electrical connector-filter (Aut. St. USSR No. 1693669, IPC H 01 R 13/00, publ. 11/23/91), containing a metal housing of cylindrical shape, contact elements in the form of conductive rods, a dielectric separating the housing and rods .

At the same time, the case is made in the form of a glass with holes in which contact elements are placed, the walls of the holes are covered with an oxide layer of the glass material, and metallization is applied on top of it. The contact elements are separated from the walls of the holes by a microwave absorbing composite material, which will create a high-frequency noise filter for each contact element together with the walls of the holes. The bottom of the glass also acts as a grounding plate.

This electrical connector filter according to the set of essential features is the closest to the claimed device and therefore is selected as a prototype.

The disadvantages of the prototype are: a high reflection coefficient of interference, low resistance to strong magnetic fields, low efficiency of noise suppression due to the same bandwidth of noise suppression filters of contact elements.

The objective of the proposed utility model is to reduce signal reflection from the connector, increase resistance to strong magnetic fields, and increase the level of noise immunity.

This problem is solved by the fact that in the electrical connector-filter,

comprising a cylindrical metal housing, inside which there are contact elements in the form of conductive rods separated from each other in the lower part of the housing and from the housing by a dielectric with holes for contact elements, a ground plate with holes for contact elements in contact with the housing, and an anti-interference high-pass filter for each contact element, in the middle part of the housing between the dielectric and the ground plate there is a screen made of radar absorbing material in the form ilindra adjacent its lateral surface to the inner wall of the housing to cover all of the contact elements, the contact elements in the upper part of the housing filled with an insulating compound. The screen of the radar absorbing material can be made in the form of a continuous cylinder with holes for contact elements.

The technical result of the proposed model is to reduce the signal reflection from the connector, increase resistance to strong magnetic interference, increase the level of noise immunity.

The achievement of the indicated technical result is explained by the introduction of a cylinder from the radar absorbing material, for example, ferrite with relative magnetic permeability into the housing of the filter connector of the cylinder

μ _rel at least 4000. Such a cylinder performs the function of a magnetic screen, as well as the function of a cable filter. If μ _{rel is} less than 4000, the screening coefficient and the absorption coefficient of electromagnetic waves in the low-frequency region are reduced, which increases the reflection of the signal and reduces the resistance to strong magnetic fields.

The increase in the noise immunity of the proposed device is determined by the possibility of installing filters on contact elements with different cutoff frequencies, in contrast to the prototype, where the cutoff frequency is the same for all filters of contact elements.

A useful model is illustrated in FIG. 1 and FIG. 2, which show two embodiments of the proposed technical solution. The proposed electrical filter connector contains (Figure 1): a cylindrical metal housing 1 with a flange, contact elements 2, a dielectric 3 with holes for contact elements, filters 4 on the contact elements 2, the screen 5 is made of radar absorbing material (for example, ferrite with μ _Rel = 4000), grounding plate 6, compound 7, insulating contact elements 2 on the right side of the housing, soldering points 8 of plate 6.

Figure 2 presents an embodiment of a screen of radar absorbing material in the form of a solid cylinder 9 with holes for contact

elements 2.

The proposed device operates as follows:

The signal passing from the source to the load through the lead wires (not shown in FIGS. 1 and 2) and contact elements 2 creates an electromagnetic field that is attenuated by a cylindrical radar absorbing screen 5 (FIG. 1) or screen 9 (for the variant of FIG. 2) . Screens 5 and 9 are attenuators for the high-frequency components of the signal spectrum. For low-frequency components, each of these screens is an additional inductance, forming with filters built into contact elements 2, LC filters of low frequencies of the 2nd or 4th order, depending on the type of filters 4 on contact elements 2.

In the prototype of the proposed device, the housing is made of brass LS-59 with a plating Sn-Bi (tin-bismuth). Case diameter 20 mm, length 30 mm. The housing contains 10 contact elements with filters, a dielectric made of AG-4 plastic, a radio-absorbing screen made of M4000NM ferrite with μ _rel = 4000, an earthing plate made of LS-62 brass with Sn-Bi electroplated coating. As an insulating compound used epoxy resin brand K-153.

Tests of the prototype showed that its coefficient

and the screening coefficient of constant magnetic fields is about 10 times higher.

As can be seen from the description of the design and the prototype, the manufacture of the device involves the use of known materials and standard technological operations, this indicates the possibility of industrial implementation of the proposed utility model.

Claims (2)

1. An electrical filter connector, comprising a cylindrical metal housing, inside which are contact elements in the form of conductive rods, separated on one side of the housing from each other and from the housing by a dielectric with holes for contact elements, and a ground plate with holes for contact elements contacting with the housing, each contact element having a high-frequency interference suppression filter, characterized in that in the middle part of the housing between the dielectric and the ground plane Astina installed a screen of radar absorbing material in the form of a cylinder adjoining with its lateral surface to the inner wall of the housing with the coverage of all contact elements that are flooded on the other side of the housing with an insulating compound. 2. The electrical filter connector according to claim 1, characterized in that the screen of the radar absorbing material is made in the form of a continuous cylinder with holes for contact elements.