RU2321932C1 - Junction assembly for composite capsule shell components - Google Patents

Abstract

FIELD: means for shielding, for instance, vehicles, against electromagnetic interference radiated by electrical equipment.

SUBSTANCE: proposed junction assembly for composite capsule shell has electromagnetic damper disposed between slot-forming surfaces of shell components being joined. Electromagnetic damper has dispersed composition or is produced from dispersed composition in the form of at least one component of low shielding coefficient, as well as at least one electromagnetic radiation absorbing component, or at least one electromagnetic radiation reflecting component, or at least one electromagnetic radiation absorbing component and at least one electromagnetic radiation reflecting component. Linear grain size of electromagnetic radiation absorbing/reflecting components is chosen from following equations, respectively:

where

is linear grain size of electromagnetic radiation absorbing component; σ_a is conductivity of electromagnetic radiation absorbing component grain material; μ_a is absolute magnetic permeability of grain material electromagnetic radiation absorbing component;

is linear grain size of electromagnetic radiation reflecting component; σ_r is grain material conductivity of electromagnetic radiation reflecting component; μ_r is absolute magnetic permeability of electromagnetic radiation reflecting component grain material; f_l is low value of damping electromagnetic radiation frequency band.

EFFECT: ability of producing junction assembly of enhanced corrosion resistance for composite capsule shell characterized in low radiation with respect to radio noise, provision for its launching in mass production.

3 cl, 2 dwg

Description

The invention relates to means of protection against electromagnetic interference emitted by electrical devices, in particular vehicles.

From the book "Instrument Design", ed. V. Krause, translation from German by V.N. Palyanov, ed. O.F. Tishchenko, M .: Engineering, 1987, volume 1, p. 314 ... 319 are known to protect capsules against electromagnetic radiation. In this case, the capsule shells can be made integrally, and composite, solid, and perforated, flexible, rigid or combined. The capsule shells are made or contain coatings of the following materials: for protection against electric fields from an electrically conductive material, for protection against magnetic low-frequency fields, from a magnetically conductive material, for protection against magnetic medium and high-frequency fields from a magnetically conductive and / or electrically conductive material. Among the shortcomings of the above capsules can be identified:

- for capsules that suppress electric fields, - stringent requirements for the galvanic purity of abutting surfaces and the need for galvanic connection of the shell with the interference receiver through possibly short connectors;

- for capsules that suppress magnetic fields - stringent requirements on the location of the joints of the shells, relative to the magnetic field lines of the fields, on the design of the joints and on the galvanic cleanliness of the mating surfaces.

From the book by R. A. Dunina, A. N. Naumov “Aviation and radio-electronic equipment of the Yak-18T aircraft”, second edition, M .: Transport, 1982, p. 97, 98 it is known: to equalize the electric potentials arising on various electrically conductive parts of the aircraft, to exclude the operation of galvanically isolated metal parts of the aircraft as emitters of electromagnetic interference, the specified forced metal. Metallization is usually carried out by bridges made of interwoven copper, often tinned, wires or strips of copper, often tinned, foil and may cover the following: controls, engine, engine frame, oil and fuel systems, cable shields, electrical equipment, control panels, units, as well as metal parts of the aircraft body. In the automotive industry, the metallization of galvanically separated metal parts is most often limited to the use of flexible copper jumpers located between the engine, frame and / or body, and between the body and hood, the locking device and the suspension components of the hood, as well as galvanic connections between the shielding of the cables and electrical equipment, if those are available, with a body and engine. The indicated can be seen, for example, in the book of A.V. Ashmarov, A.Yu. Kubyshkin. Average repair of VAZ-21099, M .; Third Rome, 2000, p. 13, FIG. 5, p. 166, FIG. 7, POS. 1, 2, 3, and also in the book of Y.E. Golodovsky, I.V. Zaitsev, O.M .Lavrova. Off-road trucks, M .: Military publishing house of the Ministry of Defense of the USSR, 1968, p. 132, Fig. 98.

Thus, almost any vehicle, and this is clearly shown in Fig. 2, see page 8 of the aforementioned book “Aviation and radio-electronic equipment of the Yak-18T aircraft”, can be considered as a combination, or at least one, made, most often , of electro- or electro- and magnetic conductive material, metallized capsules that protect against electromagnetic radiation, inside each of which is located at least one emitter of unintentional, spurious, radio interference or an object protected from interference. To provide access to the equipment located inside the capsule, its shell is either made up of at least two elements connected with the possibility of separation, or containing at least one element connected to the shell with the possibility of separation (opening, folding, biasing, removing), or consisting of at least two detachably connected elements, any of which can be made comprising at least one disconnectably connected to the shell ( opening, reclining, shifting, removing) element. The shell of the capsule and / or any of its elements can be made according to any of the types of monocoque, semi-monocoque and with the supporting frame, any of the elements of the capsule shell can be made as one-piece or composite. Thus, the shell of any really existing capsule of the serviced object that protects against electromagnetic radiation contains at least one gap located between the connected elements. The linear dimensions of any of the slots contained in the capsule shell, the profile of the opposite, forming a gap surfaces of the connected shell elements, as well as the interval between them, are determined in many cases constructively or technologically. From the point of view of electrical engineering, the gap can be considered as a horn, and as a waveguide, and as an element of communication. Therefore, one of the places where the parasitic electromagnetic field penetrates, equally from the capsule into the space surrounding it, or from the space surrounding the capsule inside the capsule, is the gap between the elements making up the capsule, and the longer the gap, the less attenuation waves with lower types of vibrations will propagate through it. .

The prototype of the invention adopted known from the materials for patent RU 2243622, 7 IPC Н01Т 13/41, publ. 2004, the junction of the shell elements of the composite capsule containing the electromagnetic buffer located between the forming gap surfaces of the connected shell elements. In this solution, the electromagnetic buffer is made in the form of a diffraction grating. The diffraction grating is formed by spacing along the perimeter of the slit, extending between the slit forming surfaces of the shell elements by electrically conductive jumpers, each of which is made with the possibility of galvanic closing of the connected shell elements. In this case, the interval (in meters) between the jumpers should not be higher than the value determined by the ratio: C / 2f _max , where C is the speed of light (3 × 10 ⁸ m / s), af _max is the maximum frequency of the damped noise spectrum (Hz).

For vehicles containing an internal combustion engine with electric spark ignition of working mixtures, one of the most powerful emitters of unintentional radio interference is the ignition system, which also generates the widest range of electromagnetic radiation. In accordance with GOST R 51318.12, the maximum measured frequency (f _max ) of broadband industrial radio interference from vehicles is 1 GHz. Therefore, the maximum distance between the jumpers of the electromagnetic buffer will be 0.15 m.

The disadvantages of the technical solution mentioned above include the obvious difficulty in implementing a diffraction grating in mass production, as well as the obvious difficulties in maintaining the galvanic closure properties of the connected shell elements over time.

The objective of the invention was the creation of a small emitting, from the point of view of propagation of radio interference, providing the possibility of implementation in conditions of mass production, as well as durable in an environment with increased corrosive activity of the junction of the elements of the shell of the shell of the composite capsule.

For an unambiguous understanding of the essence of what is described below, the applicant considers it necessary to introduce the following explanation: when in an electromagnetic field in dielectric materials, there are losses depending on both the frequency of the alternating electromagnetic field and the molecular and atomic structures of the dielectric material. Moreover, for "clean", not containing conductive components (carbon black, graphite, ferromanite materials) dielectric materials, these losses (absorption of high-frequency energy) are quite small. Based on the foregoing, the applicant identifies the following conditional categories of components:

- a component with a small screening coefficient (weakly absorbing material, the material in which the electromagnetic field attenuates weakly),

- absorbing / reflecting electromagnetic radiation component (material that increases the loss in the composition),

- damping electromagnetic radiation composition (absorbing and / or reflecting electromagnetic radiation composition having losses in the electromagnetic field).

The problem is solved at the junction of the shell elements of the composite capsule containing an electromagnetic buffer located between the gap-forming surfaces of the connected shell elements.

The problem can be solved in that the electromagnetic buffer is made of a dispersed composition damping electromagnetic radiation or containing a dispersed composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low shielding coefficient and at least one component absorbing electromagnetic radiation , the linear grain sizes of the absorbing component should not be higher than the value determined with attitude:

,

,

where f _n is the lower frequency boundary of the damped electromagnetic radiation,

σ _p - specific conductivity of the material of the grains of the absorbing component,

μ _p - absolute magnetic permeability of the grain material of the absorbing component.

The problem can be solved in that the electromagnetic buffer is made of a dispersed composition damping electromagnetic radiation or containing a dispersed composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low shielding coefficient and at least one component reflecting electromagnetic radiation , the linear grain sizes of the reflecting component should be greater than the value determined by the corresponding wearing:

,

,

where f _n is the lower frequency boundary of the damped electromagnetic radiation,

σ _o - the specific conductivity of the material of the grains of the reflecting component,

μ _about - the absolute magnetic permeability of the grain material of the reflecting component.

The problem can be solved in that the electromagnetic buffer is made of a dispersed composition damping electromagnetic radiation or containing a dispersed composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low shielding coefficient, at least one component absorbing electromagnetic radiation and at least one component reflecting electromagnetic radiation, and the linear size The grains of the component absorbing electromagnetic radiation should not be higher, and the linear grain sizes of the reflecting component should be greater than the value determined by the ratio:

,

,

where f _n is the lower frequency boundary of the damped electromagnetic radiation,

σ is the specific conductivity of the grain material, respectively, of the absorbing / reflecting component,

μ is the absolute magnetic permeability of the grain material, respectively, of the absorbing / reflecting component.

In this case, the dispersed electromagnetic damping electromagnetic radiation can be, for example, either a composite material containing a polymer matrix, or a solid solution, or a suspension, including a fluid that loses its fluidity over time, or a mechanical (loose without binder or with binder) mixture , as a component absorbing electromagnetic radiation, for example, carbon, ferrites, metals, metal alloys can be used, as a component reflecting electromagnetic radiation can be used, preferably metals or alloys thereof.

The invention is illustrated by the following drawings.

Figure 1 shows a General view of the composite capsule in relation to the car.

Figure 2 shows the junction of the shell of the composite capsule.

The invention can be implemented as follows. In relation to a car, the shell of the compound capsule protecting from electromagnetic radiation is formed by pivotally fixed fixed 1 and movable 2 metallized elements mounted with the possibility of separation (opening). The fixed element 1 of the shell of the composite capsule is formed by (not shown) a shield separating the engine compartment and the cockpit of the vehicle, the left, right and lower mudguards of the engine compartment, the radiator lining, and the radiator of the engine cooling system, which, from the point of view of electrical engineering, is a filter, consisting of many transcendental waveguides. In this case, the parts included in the fixed element 1 of the shell of the composite capsule are made, with the exception of a practically non-magnetically conductive radiator, of electric and magnetic conductive material, galvanically and mechanically connected by means of threaded and electrowelded joints. The movable element 2 of the shell of the composite capsule is represented by a hood (shown conditionally) of the engine compartment made of electric and magnetic conductive material. The fixed and movable elements 1, 2 of the shell of the composite capsule are installed with a gap, i.e. with the formation of a gap located between the connected elements. Metallization (not shown) of the fixed and movable shell elements of the composite capsule is carried out (not shown) by the hinges of the hood suspension and a flexible copper jumper. Between the gap-forming surfaces of the fixed 1 and movable 2 shell elements of the composite capsule, an electromagnetic buffer 3 is installed. The electromagnetic buffer 3 is made in the form of a profiled, including hollow (not shown), possibly reinforced (not shown), sufficiently elastic, flexible, elastic part, laid mainly around the entire perimeter of the gap and fixed by methods known in the art on a fixed 1 or moving 2 shell element of a composite capsule. When this electromagnetic buffer 3 can be performed:

1) entirely formed from a damping electromagnetic radiation dispersed composition (not shown);

2) in the form of a shell formed from a damping electromagnetic radiation dispersed composition, which, in turn, can be filled with a material with a small screening coefficient, including a fluid or gas mixture (not shown);

3) in the form, mainly, of a thin-walled shell 4 formed from a material with a small screening coefficient, which is filled with a dispersive composition 5 damping electromagnetic radiation.

The electromagnetic radiation damping dispersed composition, in the described cases, is at least one predominantly polymer component — a matrix with a low shielding coefficient, as well as at least one component that absorbs electromagnetic radiation, or at least one component that reflects electromagnetic radiation, or at least one electromagnetic radiation absorbing component and at least one electromagnetic radiation reflecting component. In this case, the linear grain sizes of the absorbing / reflecting electromagnetic radiation components are selected, respectively, from the following relationships:

,

,

_п - линейные размеры зерен поглощающего электромагнитное излучение компонента,Where

_p is the linear grain size of the component absorbing electromagnetic radiation,

f _{p the} lower frequency boundary of the damped electromagnetic radiation,

σ _p - the specific conductivity of the material of the grains absorbing electromagnetic radiation component,

μ _p - the absolute magnetic permeability of the grain material absorbing electromagnetic radiation component.

,

,

_о - линейные размеры зерен отражающего электромагнитное излучение компонента,Where

_about - the linear dimensions of the grains reflecting electromagnetic radiation component,

f _n - the lower frequency limit of the damped electromagnetic radiation,

σ _about - the conductivity of the material of the grains reflecting electromagnetic radiation component,

μ _o - the absolute magnetic permeability of the material of the grains reflecting electromagnetic radiation component.

In relation to other than automotive, areas of the invention can be implemented not shown in the drawings in the following ways.

1. The metallized shell of the composite capsule made of electrically and magnetically conductive material contains, for example, at least two lap-connected elements arranged to form a slit fastened by riveting or threaded connections. In this case, the electromagnetic buffer can be made in the form of a suspension damping electromagnetic radiation, including a suspension that loses its fluidity over time, located between the surfaces of the shell elements to be connected to form the gap. In this case, the suspension may contain at least one component — a matrix with a small screening coefficient, as well as at least one component that absorbs electromagnetic radiation, or at least one component that reflects electromagnetic radiation, or at least one component that absorbs electromagnetic radiation and at least at least one component reflecting electromagnetic radiation. The linear grain sizes of the absorbing / reflecting electromagnetic radiation components of the suspension are selected according to the above rules.

2. The metallized shell of the composite capsule made of electrically and magnetically conductive material contains, for example, a horizontally located opening for accessing the inside of the capsule and a horizontally located removable lid covering this opening. Where adjacent to the hole, the lid surface located on the lid side is provided with a cavity formed in the form of a closed belt indented from the edges of the hole, and the surface of the removable lid located on the side of the shell is provided with a protrusion formed as a closed belt entering the trough. In this case, the surfaces of the lug protrusion extending, at least in the horizontal direction, are located with a gap relative to them of the opposite surfaces of the shell cavity. In this case, the electromagnetic buffer can be made in the form of a filling located in the gap between the walls of the annular cavity and the annular protrusion. The filling can be a mechanical dispersed mixture containing at least one component with a low shielding coefficient, as well as at least one component absorbing electromagnetic radiation, or at least one component reflecting electromagnetic radiation, or at least one absorbing electromagnetic radiation component and at least one component reflecting electromagnetic radiation. The linear grain sizes of any of the components absorbing / reflecting electromagnetic radiation of the mechanical dispersed mixture are selected according to the above rules.

The technical solution according to the invention works as follows (without taking into account losses caused by vibration of the domains of conductive components in an electromagnetic field and their interaction with a component with a small screening coefficient).

1. The case of using an electromagnetic radiation damping dispersed composition containing a plurality of grains of an electromagnetic radiation absorbing component. When an electromagnetic wave falls on the grain surface of the absorbing component and penetrates into the grain body, energy is dissipated at the nodes of the crystal lattice of the substance constituting the grain in the form of heat and the interatomic transition of the electrons of the substance to higher orbitals. The decrease in the energy of the electromagnetic field as it passes through the electromagnetic buffer is mainly due to the absorption of the electromagnetic field by the grains of the absorbing component. The energy of the electromagnetic field at the output of the electromagnetic buffer, in a given frequency band, is inversely proportional to the total conductivity of the grains of the absorbing component and the total grain thickness in the direction of passage of the electromagnetic field.

2. The case of using an electromagnetic radiation damping dispersed composition containing a plurality of grains of a component reflecting electromagnetic radiation. When an electromagnetic wave is incident on the grain surface of a reflecting component (having high conductivity, the linear dimensions of which are greater than the penetration depth of the electromagnetic field into the substance of the reflecting component at the maximum wavelength of the frequency range), its predominant reflection occurs. Given that the composition damping electromagnetic radiation is dispersed, the electromagnetic wave, penetrating to a certain depth of the electromagnetic buffer, is repeatedly reflected from the surfaces of the grains of the reflecting component located on the path of its propagation, gradually scatters and decays.

3. In the case of using an electromagnetic radiation damping dispersed composition containing grains and absorbing and reflecting electromagnetic radiation components, the processes described above proceed. The decrease in energy at the output of the electromagnetic buffer in this case occurs due to the absorption of the electromagnetic field by the grains, mainly the absorbing component, and due to its reflection and dispersion by the grains, mainly the reflecting component. The energy of the electromagnetic field at the output of the electromagnetic buffer, in this frequency band, is inversely proportional to the total conductivity of the grains of the absorbing component, magnetic permeability and linear grain sizes of the reflecting component, as well as the total grain thickness of the absorbing component in the direction of passage of the electromagnetic field.

Thus, the technical solution according to the invention allows you to create a low-emitting, from the point of view of the propagation of radio interference, durable in the environment with high corrosion activity site of the junction of the shell elements of the composite capsule and provides the possibility of its implementation in mass production.

Claims (3)

1. The junction of the elements of the shell of the composite capsule containing an electromagnetic buffer located between the gap-forming surfaces of the connected shell elements, characterized in that the electromagnetic buffer is made of a dispersed composition damping electromagnetic radiation or containing a dispersive composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low screening coefficient and, at least one component absorbing electromagnetic radiation, the linear grain sizes of the absorbing component should not be higher than the value determined by the ratio

where f _n is the lower frequency boundary of the damped electromagnetic radiation; σ _p - specific conductivity of the material of the grains of the absorbing component; μ _p - absolute magnetic permeability of the grain material of the absorbing component. 2. The junction of the elements of the shell of the composite capsule containing an electromagnetic buffer located between the slit-forming surfaces of the connected shell elements, characterized in that the electromagnetic buffer is made of a dispersed composition damping electromagnetic radiation or containing a dispersive composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low screening coefficient and, at least one component reflecting electromagnetic radiation, the linear grain sizes of the reflecting component must be greater than the value determined by the ratio

where f _n is the lower frequency boundary of the damped electromagnetic radiation; σ _about - the specific conductivity of the material of the grains of the reflecting component; μ _about - the absolute magnetic permeability of the grain material of the reflecting component. 3. The junction of the elements of the shell of the composite capsule containing an electromagnetic buffer located between the slit-forming surfaces of the connected shell elements, characterized in that the electromagnetic buffer is made from a dispersed composition damping electromagnetic radiation or containing a dispersed composition damping electromagnetic radiation, the dispersed composition damping electromagnetic radiation includes at least one component with a low screening coefficient, n at least one electromagnetic radiation-absorbing component and at least one reflecting electromagnetic radiation component, the linear dimensions of grains electromagnetic radiation absorbing component should not be higher and the linear dimensions of the grains of the specular component should be greater than the value determined by the relation

where f _n is the lower frequency boundary of the damped electromagnetic radiation; σ is the specific conductivity of the grain material, respectively, of the absorbing / reflecting component; μ is the absolute magnetic permeability of the grain material, respectively, of the absorbing / reflecting component.

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