RU112578U1 - FLEXIBLE PRINT CABLE CONNECTION WITH RIGID PRINT CABLE - Google Patents

Abstract

The utility model relates to the field of electrical installation, namely to the connection of flat cables (loops) with rigid printed circuit boards used in the manufacture of electronic and electronic equipment. The technical result of the proposed technical solution is to create a highly reliable connection of a flexible printed cable with a rigid printed circuit board, simplifying the wiring of the structure. This is achieved by the fact that the connection of the flexible printed cable to the rigid printed circuit board, containing soldered connection of the contact pads of the rigid printed circuit board and the terminals of the flexible printed cable, in which metallized holes are made, is installed in the metallized holes of the flexible printed cable and the rigid printed circuit board least one bracket. Moreover, the polygons of a flexible printed circuit board and a rigid printed circuit board are connected by soldering. Moreover, between the flexible printed cable and the rigid printed circuit board an elastic element is installed (1 n.p., 2 z.p. files, 3 ill.).

Description

The utility model relates to the field of electrical installation, namely to the connection of flat cables (loops) with rigid printed circuit boards used in the manufacture of electronic and electronic equipment.

From the point of view of saving weight and space, of the whole variety of flat cables, flexible printed cables are the most promising. They have a significant feature due to the manufacture of printed conductors from galvanic copper foil with a thickness of 35-70 microns or by vacuum deposition: low mechanical strength, which requires measures to protect the transition from the flexible part of the node to its hard part. Quite often, flexible printed cables are required to repeatedly bend.

A flexible printed cable is a flexible dielectric base, for example, of polyimide with conductors made on its surface coated with a protective dielectric film, so that electrical leads are created on the edges of the flexible printed cable (E.V. Pirogov “Design and technology of printed circuit boards” , (textbook), FORUM-INFA-M, Moscow, 2005, chap. 1-2). It is possible to make findings of printed cables in the form of pads. They represent sections of printed conductors, bare and tinned on one side.

The connection of flexible printed cables with rigid printed circuit boards is carried out in most cases by soldering the contact pads (pins) of flexible printed cables with the contact pads of boards in various ways: thermal compression soldering, infrared soldering, manual soldering. All these compounds are characterized by the need to protect (strengthen) the leads in the soldering area.

As a rule, the small thickness of a rigid board of 0.2-0.5 mm does not allow it to twist its edges, and with repeated bending of a flexible printed circuit board at the points of contact, destruction of the flexible printed circuit board may occur.

To prevent the destruction of the terminals of the flexible printed circuit board, hardening of the solder joint at the place where the conductors exit from the insulation with the help of additional supports is used.

A technical solution is known (RF Patent No. 2308177, H05K 1/11, H01R 12/24, publ. 2007.10.10), which is a printed cable with beam terminals, in which hardening of the soldered connection is achieved by the fact that at least one of the beam terminals is equipped with various types of additional supports or (and) end clamp. The disadvantages of the analogue: a large number of additional elements (supports and / or end clamps), which in themselves require fixing parts and / or nodes, which significantly complicates the design.

The closest technical solution (prototype) is a technical solution (Application WO 2005FR01357, Н05К 3/00, Н05К 3/36, publ. 2006.01.05), in which the connection of a flexible printed cable and a rigid printed circuit board is provided using adhesive between the boards with subsequent soldering conductive paste through at least one pair of additional metallized holes in the flexible printed circuit board and in the rigid printed circuit board. The hardened conductive paste and adhesive are additional supports. The disadvantages of the prototype: at the boundary of the protective film of the flexible printed circuit board and the conductor, bending of the flexible printed circuit board is possible, which can lead to its breakage and product failure, which significantly reduces reliability. The sharp edges of a rigid circuit board with frequent bending of the flexible cable can lead to its destruction, which also reduces reliability. The prototype involves the stage of the exact alignment of the conductors when gluing a flexible printed circuit board, which is an additional responsible operation, which is time-consuming and leads to a significant complication of wiring.

The technical result of the proposed technical solution is to create a highly reliable connection of a flexible printed cable with a rigid printed circuit board, simplifying the wiring of the structure.

The technical result is achieved by the fact that the connection of the flexible printed cable to the rigid printed circuit board containing soldered connection of the contact pads of the rigid printed circuit board and the terminals of the flexible printed cable, in which metallized holes are made, is installed in the metallized holes of the flexible printed cable and the printed circuit board, at least one bracket. Moreover, the polygons of a flexible printed circuit board and a rigid printed circuit board are connected by soldering. Moreover, between the flexible printed circuit board and the rigid printed circuit board an elastic element is installed.

The essence of the utility model is illustrated by drawings, where

Figure 1 - connection of a flexible printed circuit board with a rigid printed circuit board using a bracket;

Figure 2 - flexible printed circuit board with leads, metallized holes and polygons;

Figure 3 - a rigid printed circuit board with pads and metallized holes.

Flexible printed circuit board 1 (Fig. 1) contains printed conductors 2, coated with insulation 3 with leads 4 (Figs. 1, 2), metallized holes 5, polygons 6, not electrically connected to the conductors 2 (Fig. 1).

Rigid printed circuit board 7 (figure 3) contains pads 8, metallized holes 9, polygons 10, not electrically connected with pads 8.

The proposed connection contains a flexible printed circuit board 1 (Fig. 1) with leads 4 soldered to the contact pads 8 of the rigid printed circuit board 7, an additional support in the form of a bracket 11 made, for example, of copper wire installed in metallized holes 5, 9, polygons 6 GPK 1, soldered to the polygons 10 of the rigid circuit board 7. The bracket 11 is located outside the output region 12 of the conductors 2 from the insulation 3. Between the flexible circuit board 1 and the rigid circuit board 7 is an elastic element 13 in the form of a plate, for example, made of rubber.

The operation of the device is as follows. When connecting a flexible printed circuit board 1 with a rigid printed circuit board 7, the brackets 11 are inserted into the metallized holes 5, 9 and they are mutually fixed, while the contact pads 8 of the rigid printed circuit board 7 and the conclusions 4 of the flexible printed cable 1 are automatically combined. Next, the soldering process is carried out. When the flexible printed circuit board 1 is bent, the bracket 11 perceives all stresses and deformations, while in the places of the rations of the contact pads 8 and conclusions 4 they are practically absent. The connected polygons 6, 10 also perceive part of the stresses.

The elastic element 13, installed between the flexible printed circuit board 1 and the rigid printed circuit board 7, redistributes the stresses arising on the sharp edges of the rigid printed circuit board 7 and eliminates the occurrence of stress concentrators at the touch points of the flexible printed circuit board 1 and the rigid printed circuit board 7 and, thus, guarantees elimination of the influence of sharp edges of the rigid printed circuit board 7 on the flexible printed circuit board 1. Therefore, the possibility of destruction of the flexible printed circuit board 1 is eliminated and the reliability of the obtained connection is increased.

In contrast to the prototype, the distinguishing features of the claimed invention can improve the reliability of the connection of the flexible printed cable with a rigid printed circuit board, which is achieved by fixing the flexible printed circuit board to the rigid printed circuit board by installing the brackets in their metallized holes and then soldering the flexible printed cable with a rigid printed circuit board. At the same time, the installation of the bracket ensures accurate alignment and fixation of the connected parts, and this greatly simplifies the wiring of the structure. Soldering polygons of a flexible printed circuit board and a rigid printed circuit board, as well as installing an elastic element between them, can further improve the reliability of the created connection by eliminating the possibility of destruction of the flexible printed cable.

The claimed utility model has differences from the closest analogue, thus, it satisfies the condition of patentability “novelty”.

The utility model can be used in the development of flexible-rigid printed circuit boards to provide connections in the electrical circuits of a wide range of radio and electronic equipment.

The technical solution can be implemented at the instrument-making enterprise. The description contains the material means for its implementation. In this regard, the claimed utility model meets the patentability condition “industrial applicability”.

Claims (3)

1. The connection of the flexible printed cable with a rigid printed circuit board, comprising a soldered connection of the contact pads of the rigid printed circuit board and the terminals of the flexible printed cable, in which metallized holes are made, characterized in that the metallized holes of the flexible printed cable and the rigid printed circuit board are installed, at least one bracket. 2. The connection according to claim 1, characterized in that the polygons of the flexible printed cable and the rigid printed circuit board are connected by soldering. 3. The connection according to claim 1 or 2, characterized in that between the flexible printed cable and a rigid printed circuit board is installed an elastic element.