RU2037279C1 - Radioelectronic unit - Google Patents

Abstract

FIELD: radio electronics. SUBSTANCE: provision is made for parametric adjustment of device case and recovery of its initial shape. Functional assembly 1 is covered with flexible conducting jacket 3 made of woven and knitted material and placed inside damper 4 made of woven material or gas-filled elastic polymer; case is essentially external shell 5 of damper 4 made of high-strength water-resistant material, such as leather or water-proof fabric joined to form desired shape by stitching or welding. With seams of external shell 5 and special internal jacket of damper 4 providing adequate sealing, gas medium of desired characteristics may be admitted. Jointing, check-up, and control elements are placed inside damper 4 and fixed to external shell 5. EFFECT: improved reliability under conditions of accidental impact and alternating loads of comprehensive spectrum. 6 cl, 3 dwg

Description

 The invention relates to electronics and can be used in the design of devices to be used in the conditions of random application of shock and alternating dynamic loads.

 A radio electronic block is known, comprising a housing, subunits installed therein on printed circuit boards with handles, connected by connectors to a patch panel, and a cover with gaskets of elastic material placed between the inner surface of the cover and the handles of the subunits in the grooves of the cover. Gaskets are made in a stepped form with a certain ratio of parameters (1).

 The implementation of gaskets made of step-shaped elastic material makes it possible to damp the vibration energy when exposed to alternating dynamic loads and to protect the boards from them. Given that the main share of disturbances has a small frequency, and to solve the problem of vibration isolation, it is necessary to give shock absorbers greater flexibility, it is advisable to make gaskets based on woven materials that have better elastic-dissipative characteristics in the lower frequency range. In addition, under conditions of accidental application of shock loads, body deformations can be beyond the elastic limit of the structural material, which entails a change in the appearance of the device up to breakdowns.

 Closest to the technical nature of the claimed one is a radio-electronic unit selected as a prototype, comprising a housing with a damper rigidly fixed inside it, made in the form of fabric rollers connected to each other by woven material, and a functional unit mounted on a damper. At the same time, the damper is equipped with a two-layer shell installed in the housing (2).

 When external dynamic loads are applied to the block, dry friction occurs between the layers of the woven material of the rollers, which provides damping of vibrational energy and generates electric charges. At the same time, the latter flow through the outer shells of the damper onto the block body, preventing the functional unit from being affected by static electricity.

 This system solves the problem of damping the energy of alternating loads in a narrow, predetermined range. To solve the problem of vibration isolation in a wide range of alternating loads, since the frequency, amplitude and points of application of loads in a real situation are random, it is necessary to change the system stiffness in proportion to the load. The case, as in the analogue, does not restore its original shape after removing shock loads.

 The aim of the invention is to increase reliability in the case of accidental application of a wide range of shock and alternating loads by giving the body of the device the possibility of parametric adjustment and restoration of its original form.

 This goal is achieved by the fact that in the case with the damper rigidly fixed inside it in a two-layer shell and the functional unit mounted on the damper, the functional unit is covered with an elastic electrically conductive shell and placed inside the damper volume made of porous elastic material, and the body is made in the form of an outer shell a damper made of a moisture-resistant durable material, for example, leather or its substitutes, wherein the connection, control and control bodies are located in the damper volume and are rigidly attached to the outer shell; as porous elastic material of the damper can be used woven materials, gas-filled elastic polymers or a gas medium.

 In FIG. 1 is a cross-sectional view of a device body; in FIG. 2 case of the device in interaction with alternating load; in FIG. 3 case of the device when exposed to shock load.

 The housing of the device contains a functional unit 1, for example, an electronic printed circuit board in a rigid frame 2, covered with an elastic conductive sheath 3, made, for example, of woven or knitted material with the inclusion of conductive threads and threads with a high modulus to break, placed inside the volume of the damper 4, made made of woven fabric or gas filled elastic polymer. The outer shell 5 is made of a moisture resistant durable material, for example leather, artificial leather or moisture resistant fabric, connected in shape by sewing or welds. Given the tightness of the seams with the outer shell 5 and a special coating of the shell 3, the damper can be a gas medium with the required characteristics. The bodies of the connection 6, including the grounding connector 7, control 8 and control 9 are placed in the volume of the damper 4 and are rigidly attached to the outer shell 5.

 During operation of the device, the outer shell 5 gives it an external shape with the desired location of the connection elements 6, control 8 and control 9 and protects the device from external mechanical, hydro- and gas-dynamic loads, as well as temperature fields.

 An alternating dynamic load acts on the housing through a spot of contact with the outer shell 5 (Fig. 2). The contact spot may increase due to the possibility of load distribution by the outer shell 5 and, accordingly, the parallel involvement of new "elementary volumes" of the damper 4 in the deformation, that is, the rigidity of the system changes in proportion to the load placed on it, the vibration protection system is parametrically tuned while maintaining the optimal frequency of natural vibrations at random alternating load.

 When exposed to alternating dynamic load between the layers of woven material of the damper 4 as a result of dry friction, electric charges are generated that flow down the electrically conductive shell 3 and connector 7 to the ground, protecting the functional unit 1 from the influence of static electricity.

 In the case of application of the shock load (Fig. 3), the impulsive energy is absorbed not only by deformations of the outer shell 5 and damper 4, but also by stretching the shell 3. The energy is quenched with the initial shape of the outer shell 5 being restored.

 The use of the proposed housing can improve the reliability of the device under the conditions of random application of a wide range of shock and alternating mechanical, hydro- and gas-dynamic loads.

 In addition, the materials recommended as damper 4 are good heat insulators, which allows us to simultaneously perform the tasks of thermal stabilization of the device.

Claims (6)

 1. RADIOELECTRONIC BLOCK, containing a functional unit with connection, monitoring and control bodies, a damper with an external shell, which is rigidly connected to a functional unit, characterized in that the functional unit is equipped with a rigid frame and a shell of elastic conductive material, the damper is made of elastic material and the outer shell of the damper is made of moisture-resistant durable material, and the functional unit is mounted on a rigid supporting frame and together with it is placed in the specified shell of el adic conductive material, wherein the functional unit with a rigid shell supporting framework and placed in the cavity damper, the wall of which is rigidly connected to the shell, and a compound of organs, monitoring and control are arranged in the volume of the damper and is rigidly connected to the outer cover of the damper.  2. The block according to claim 1, characterized in that the damper is made of porous elastic material.  3. The block according to paragraphs. 1 and 2, characterized in that leather is used as a moisture-resistant durable material of the outer shell of the damper, and woven material is used as the elastic porous damper material.  4. The block according to claim 3, characterized in that skin substitutes are used as the skin of the outer shell.  5. The block according to claim 1, characterized in that a gas-filled elastic polymer is used as the elastic material of the damper.  6. The block according to claim 1, characterized in that the gas medium is used as the elastic material of the damper, while the outer shell of the damper and the shell of the functional unit are sealed.