RU2749994C1 - Method for tracing conductors of modal filter based on flat cable - Google Patents

Abstract

FIELD: radio electronics.

SUBSTANCE: invention relates to radio electronics, it can be used for protection of radio electronic equipment (REE) from ultrashort pulses (USP). A method for tracing round conductors is proposed, including tracing central reference conductor, on the edges of which two other conductors are symmetrically placed. Each conductor is placed inside the internal round dielectric layer, and all the structure is placed inside the external dielectric layer. The length of conductors is selected in such a way that its product by the module of the difference in the linear delays of the modes is not less than the sum of the front durations, the flat top, and the decay of the pulse fed between the first and the reference conductors, characterized in that the second conductor is hollow.

EFFECT: reduced weight of the conductors while preserving the decomposition of the interference pulse into a sequence of pulses of lower amplitude.

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Description

The invention relates to electronics and can be used to protect electronic equipment (REA) from ultrashort pulses (SKI).

The continuously growing complexity of modern electronic equipment leads to an exacerbation of the problem of ensuring electromagnetic compatibility (EMC). Protection of electronic equipment from conducted noise is one of the main tasks of EMC. The conductive method of propagation of interference signals implies their penetration into the electronic equipment directly along the conductors. Especially dangerous are SQIs, which are powerful pulsed signals of short duration (nano- and subnanosecond ranges) with a wide spectrum, the impact of which can lead to various negative consequences in the operation of CEA. Meanwhile, traditional means of protection against impulse noise have a number of disadvantages (vulnerability to radiation, short service life, failure to operate at high voltages, insufficient speed, etc.) that complicate protection against powerful SQI, which, in turn, requires research. additional measures for the protection of electronic equipment. In addition, devices are known that operate on the principle of modal filtering: modal filters (MF) and meander delay lines (or protective meanders). Due to the strong connection between the active and passive (s) conductors, in such devices there is a possibility of decomposition of the acting SQI into a sequence of pulses of lower amplitude. Meanwhile, along with high performance, practice requires simplicity of implementation, low weight and low cost of protection devices, therefore, their further improvement is urgent.

The closest to the claimed technical solution is the method of modal pulse decomposition in the cable [I.E. Samotin. Protection devices for computer technology and control systems by modal decomposition of interference pulses in cable and strip structures. Diss. for a job. uch. Art. Cand. tech. sciences. - Tomsk, 2011. - 199 pp.], When flat three-wire power cables, along with their main purpose, can be used as protection against impulses, the duration of which is less than the delay difference of the cable modes.

The disadvantage of this technical solution is the use of a passive conductor, which increases the weight of the product.

A method for tracing round conductors is proposed, including tracing a central reference conductor, along the edges of which two other conductors are symmetrically located, each conductor is placed in an inner circular dielectric layer, and the entire structure is placed in an outer dielectric layer, the length of the conductors is chosen so that its product by the modulus of the difference linear delays of modes are not less than the sum of the durations of the front, flat top and fall of the pulse supplied between the first and the reference conductors, characterized in that the second conductor is made hollow.

The technical result is a reduced mass of conductors while maintaining the decomposition of the interference pulse into a sequence of pulses of lower amplitude. The technical result is achieved through the use of a hollow passive conductor. This method opens up the possibility of protection against interference with a reduced mass of conductors, which is extremely important, for example, for the space industry. The above qualitative assessments of the attainability of the technical result are confirmed by the quantitative assessments given below, obtained by means of modeling.

The achievability of the technical result is demonstrated by the example of the propagation of impulse noise with an EMF of 1 V and durations of the front, fall and flat top 100 ps each in a structure 100 cm long (Fig. 1), where r ₁ is the radius of the conductors (0.0892 cm), r ₂ is the radius of the inner dielectric layer (0.1375 cm), r ₃ is the radius of the outer dielectric layer (0.2 cm), g is the wall thickness of the hollow conductor (0.01 cm), a × b are the dimensions of the structure (0.96 × 0.4 mm), ε _r1 is the relative dielectric constant of air (1), ε _r2 is the relative permittivity of the inner dielectric layer (3), ε _r3 is the relative dielectric constant of the outer dielectric layer (3). Conductors 1 and 2 are placed in an inner circular dielectric layer and are located symmetrically to each other on different sides of the inner dielectric layer around the reference conductor, and the second conductor is hollow.

FIG. 2 shows the equivalent diagram of the structure. It consists of two (not counting the reference) conductors of length l equal to 100 cm.The first conductor is connected at one end to a source of pulse signals, represented in the diagram by an ideal source of EMF E with an internal resistance R _G , and at the other end is connected to the protected circuit, represented in the diagram by the equivalent resistance R _N. Resistors R are connected at the beginning and end of the second (passive) conductor. The values of the resistors R _G , R _H and R are taken equal to the geometric mean of the wave impedances of the even (61.1 Ohm) and odd (86.2 Ohm) modes, equal to 72.6 Ohm.

FIG. 3 shows the forms of the EMF and voltages at the input and output of the structure with a hollow passive conductor. It can be seen that when it passes through the line, the SQI is decomposed into 2 pulses. The maximum output voltage is 0.249 V and does not exceed 50% of half the EMF.

The cross-section parameters and the line length ensure the condition

where Δτ is the difference in linear delays of the line modes, and t _r , t _d , t _f are the durations of the front, flat top and falloff of the pulse, respectively.

The fulfillment of condition (1) ensures the decomposition of the initial signal into mode pulses, the linear delays of which are equal to 5.06 and 5.6 ns / m (calculated as the square root of the eigenvalues of the product of the linear coefficients of electromagnetic (L) and electrostatic (C) induction matrices) ... The value of the difference between the linear delays of the modes is equal to 0.54 ns / m, therefore, the complete decomposition of the SQI with duration t _Σ in a transmission line section of length l is possible under the condition

Taking into account conditions (1) and (2), for the indicated values of the line parameters, the maximum duration of the input signal t _Σ with a line length of 100 cm is 0.54 ns.

For r ₁ = 0.0892 cm, g = 0.01 cm l = 100 cm and copper density ρ = 8.96 g / cm ^{3, the} volume of a solid conductor is calculated using the expression

The volume of the solid conductor is 2.5 cm ³ . The mass of a solid conductor is calculated as

The mass of a solid conductor is 22.4 g. The volume of the conductor cavity is calculated using the expression

The volume of the conductor cavity is 1.97 cm ³ . Then the mass of the hollow conductor is calculated as

The mass of the hollow conductor is 4.7 g, which is almost 5 times less than the mass of the solid conductor.

Thus, the technical result is shown - a reduced mass of conductors while maintaining the decomposition of the interference pulse into a sequence of pulses of lower amplitude.

Claims (1)

A method for routing round conductors, including routing a central reference conductor, along the edges of which two other conductors are symmetrically located, each conductor is placed in an inner circular dielectric layer, and the entire structure is placed in an outer dielectric layer, the length of the conductors is chosen so that its product by the modulus of the difference in linear mode delays are not less than the sum of the durations of the front, flat top and fall of the pulse supplied between the first and the reference conductors, characterized in that the second conductor is made hollow.

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