RU2310936C1 - Current-carrying cable (alternatives) and current-carrying conductor - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: proposed current-carrying cable has insulated current-carrying conductors covered with insulating sheath and connected at ends to contact assemblies. Insulating sheath is essentially band with current-carrying conductors connected at its edges to provide for regulating conductor-to-conductor capacitance and spaced minimum 4 cm apart on band section between contact assemblies; mentioned band is made for interconnecting its edges at least on part of its length for driving current-carrying conductors together. Current-carrying conductor used for proposed cable has two insulated wires covered with common insulating sheath. Both wires are stranded over conductor length; stranded wires are essentially equal-length conductors alternately stranded clockwise and counter-clockwise and having equal number of turns and twisted with equal force.

EFFECT: ability of regulating conductor-to-conductor capacitance over perimeter.

4 cl, 12 dwg

Description

The invention relates to electrical engineering, in particular, to the design of a conductive cable used in consumer electronics for various inter-unit and component connections of audio and video.

A conductive cable is known that contains two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to the contact nodes (Article Kunegin SV "Chapter 3. Coaxial cables", laid out online on the Internet at : http://www.aboutphone.info/kunegin/coax/page3.html).

From the same source, a conductive core is known, containing two conductors isolated from each other, located in a common insulated sheath.

The specified well-known decision was made as a prototype for all declared objects.

In the known coaxial cable, the main transmission current is concentrated on the inner surface of the outer conductor, and the interference current is concentrated on the outer side of the outer conductor. Both the main current and the interference current penetrate into the thickness of the conductor only to a depth determined by the coefficient of eddy currents. Moreover, the higher the frequency, the more these currents move away from each other and, therefore, the better the cable is protected from extraneous interference. Thus, unlike all other types of cables, which require special measures for protection against interference (balancing, shielding, etc.), in coaxial cables at high frequencies this is ensured by their very design. At high frequencies, the internal inductance of the conductors is small and the inductance of the coaxial cable is determined only by the external inductance. In the calculations for using a coaxial cable, it is assumed that the resistance along the circuit is R = 0, since the losses in the cable conductors and the external interconducting inductance of the coaxial cable L = (μ / 2π) ln (r _b / r _a ) are not taken into account. Accordingly, the conductivity C = 2πσ / ln (r _b / r _a ), the capacitance C = 2πε / ln (r _b / r _a ), where μ, ε, σ are the magnetic, dielectric permittivity and conductivity of the medium, respectively, and r _b , r _a are the radii of the conductors determined from the common center of the internally located conductor.

It follows from the foregoing that the main advantages of a coaxial cable (low attenuation and high noise immunity) are especially pronounced in the high-frequency part of the transmitted frequency spectrum. At constant current and at low frequencies, when the current practically passes through the entire cross section of the conductor. The advantages of this cable disappear. Moreover, the coaxial circuit as asymmetric with respect to other circuits and the earth (the parameters of its conductors “a” and “b” are different) in the low frequency range is inferior to symmetrical cables in terms of protection against interference.

The disadvantage of this cable is that it works well in terms of noise immunity in the high-frequency part of the transmitted frequency spectrum, in the low frequency range it is inferior to symmetrical cables in noise protection. At the same time, in consumer electronics, conductors for transmitting signals in the low frequency range are just used for various inter-unit and component connections of audio and video. In this regard, cable parameters such as inter-conductor capacitance have to be taken into account, since modern equipment (audio and video assignments) is based on the use of low currents in the low frequency range, and the transfer of electric charge from one conductor to another affects the cleanliness of signal conductor. Studies have shown that the interconductor capacitance in the cable reaches 75 pF, which is a significant interference for low-current signals and sufficient to introduce distortions into such a signal.

The present invention is directed to solving a technical problem of eliminating the influence of current flow processes in a conductor on a useful signal.

The technical result achieved in this case is to improve the operational characteristics of the conductive cable by reducing the influence of the interconducting capacitance (mutual electrical intensity of the two conductors) on the quality and reliability of the transmitted signal.

In this case, the technical result for the first embodiment is achieved by the fact that in a conductive cable containing two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to the contact nodes, to ensure regulation of the interconductor capacitance parameter, the insulating sheath is a tape, along the edges of which conductive conductors are fixed, located on the tape in the area between the contact nodes at a distance of at least 4 cm from each other, while the specified tape in made with the possibility of connecting its edges with each other at least on a part of its length for rapprochement of conductive conductors.

The technical result for the second embodiment is achieved by the fact that in a conductive cable containing two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to the contact nodes, to ensure regulation of the conductive capacitance parameter, conductive conductors located at a distance from each other in the area between the contact nodes, interconnected along the length of the lock type "lightning" to remove these cores from each other when unfastening the latter.

The technical result is also achieved by the fact that in a conductive conductor containing two insulated conductors located in a common insulated sheath, both conductors in this sheath are made twisted along the length of the conductive core, while twisting is an alternating clockwise twisting lengths of equal length arrow and sections of the twist counterclockwise, having an equal number of turns in each twist.

These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present invention is illustrated by specific examples of execution, which, however, are not the only possible, but clearly demonstrate the ability to achieve the desired technical result.

Figure 1 - General view of the cable according to the first embodiment;

figure 2 is a view of the cable in cross section according to figure 1 after connecting the edges of the tape;

figure 3 - General view of the cable according to the second embodiment;

4 is an example of a cable;

5 is a diagram of the twisting of conductors in a cable;

6 is an image of the relative position of the conductors in the conductive core when twisting;

Fig.7 is a section of a conductive core of Fig.6;

Fig.8 is a section of a conductor in a conductive core of Fig.6;

Fig.9 is a graph of the change in the amplitude of the audio signal from the frequency in the spectrum of audible frequencies, for a cable with an interconductor capacity of 5 pF;

figure 10 is a graph of the dependence of the amplitude of the audio signal on the frequency in the spectrum of audible frequencies, for a cable with an interconductor capacity of 8 pF;

11 is a graph of the dependence of the amplitude of the audio signal on the frequency in the spectrum of audible frequencies, for a cable with an interconductor capacity of 12 pF;

Fig - graph of the dependence of the amplitude of the audio signal on the frequency in the spectrum of audible frequencies, for a cable with an interconductor capacity of 16 pF.

According to the present invention, a current-carrying cable design for use in consumer electronics for various inter-unit and component audio and video connections is considered. More specifically, this cable is used to connect blocks of acoustic or video systems, which have high demands on the quality of the transmitted signal. In the framework of the present invention, a current-carrying cable with a reduced interconducting capacity is considered, which can significantly increase the reliability of the signal transmitted from one component of the system to another.

Traditionally produced current-carrying cables, regardless of the design and materials used, have an interconducting capacitance equal to about 75 pF. As a result of research, it was found that when the conductive conductors are spaced apart from each other by a distance of at least 4 cm, a decrease in the cable’s interconductor capacitance to 5 pF is significantly achieved. The restriction on the lower limit is due to the fact that spaced conductive conductors at their ends are brought closer to connect with contact nodes.

According to the first embodiment, the conductive cable (Fig. 1) comprises two conductive conductors 1 isolated from each other, placed in an insulating sheath 2, and the ends of which are connected to contact nodes (not shown). To ensure regulation according to the parameter of the semiconductor capacitance, the insulating sheath is a tape 3, on the edges of which conductive conductors are fixed, located on the tape in the area between the contact nodes at a distance of at least 4 cm from each other, while this tape is made with the possibility of connecting its edges between at least part of its length for rapprochement of conductive conductors (figure 2). At the end sections, the tape is made with a notch 4 between the conductive cores to ensure the possibility of rapprochement of the free ends of the conductive conductors and their connection with the contact node. The ability to connect the edges of the tape to each other (as shown in figure 2) at least on a part of its length to bring conductive wires closer is provided by the fact that the edges of the tape are made as elements of the Zip-Lock 5 lock, which is widely used for packaging plastic bags or fasteners - zippers or sliding fasteners. Thus, to change the characteristics of the cable according to the parameter of the interconductor capacitance, it is necessary to connect the edges of the tape to each other and to achieve the required parameter by moving the zipper.

Figures 9-12 show graphs of changes in the amplitude of the audio signal versus frequency in the spectrum of audible frequencies for the cable. At the same time, by changing the length of the connected portion of the tape, we obtained graphs for cables with an interconductor capacity of 5 pF, 8 pF, 12 pF, and 16 pF. As can be seen from the graphs, with an increase in the interconductor capacitance, the useful signal begins to be strongly distorted.

According to the second embodiment, the conductive cable (Fig. 3), as in the first embodiment, contains two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to the contact nodes. However, to ensure regulation of the parameter of the semiconductor capacitance, the conductive conductors located at a distance from each other in the area between the contact nodes are interconnected along the length of the "lightning" lock 6 to remove these wires from each other when unfastening the latter. In this conductive cable, the regulation of the parameter of the interconducting capacitance is carried out by diluting the initially brought together conductive conductors.

For the indicated versions of the conductive cable, a conductive core of two insulated conductors 7 located in a common insulated sheath is used. Each conductor is made of a conductive wire (core) covered with an insulated varnished coating 8, covered by an insulating fabric 9. However, in this shell both conductors are twisted along the length of the conductive core (Fig. 5.6), while twisting is alternating equal in the lengths of the twisting sections in a clockwise direction and the sections of twisting in a counterclockwise direction, having an equal number of turns in each twisting. In each twist, the conductors are twisted with the same twisting force. The specified parameters of the conductive core are essential and determining for the process of charge transfer from one conductor to another. Thus, the core is a successively arranged alternating sections, on one of which the conductors are twisted in one direction, and on the next section, the same conductors are twisted in the opposite direction with the formation of a “reverse” zone 10 between the sections (Fig.6).

With this design, mutual cancellation of the twist of the interconductor capacitance formed in one section occurs with one sign equal in magnitude but opposite in sign to the capacitance formed in the next section.

The invention allows to design radio engineering with a minimum pF: not more than 25 pF when an audio or video signal passes through a conductor having a minimum pF - interconductor capacitance with a negative conductor passing in parallel. The invention makes it possible to ideally design an audio (video) circuit having a minimum “stray” capacitance, thereby obtaining ideal indicators in the audio (video) path, not only in the timbre of the HF-MF-LF range in the frequency response (amplitude-frequency characteristic), but also in tones of tonal balance. The highest sound signal transmission through the conductor directly depends not only on the resistance parameters, as previously thought (this parameter minimally affects the nature of the sound signal), and inductance (this parameter affects the low-frequency range not in the most basic component of the audible range and can be easily solved using the reversed conductor) and, as it turned out, the most important electrical parameter affecting the most audible part of the sound signal perceived by the human ear in the range from 800 Hz to 16500 kHz (namely up to 1650 0 visual perception by the ear increases with a decrease in the indicator of the interconductor capacitance), is the indicator in pF of the interconductor capacitance between the plus and minus of the conductor transmitting the signal (s). Between two parallel conductive and conductors - positive (+) and negative (-), the values of the interconductor capacitance in the digital pF values are so minimal that one unit in the pF capacitance (unit of capacitance) between the conductors has a serious effect on the final result of the audio or video signal. The capacitance indicators in 1 pF steps have a huge difference in values not only visually in the real audible range of the human ear and real visibility of the eyes, but they are also clearly reflected in the measuring sound graphs of the frequency response and on the test video grids. The lower the inter-conductor capacitance in pF, the cleaner the audio or video signals. According to numerous measurement experiments, practice has shown that 100% of the world's conductive interconnect interconnect cables produced have indicators from 50 to 300 pF of interconductor capacitance per linear meter. It is due to the minimum numerical indicator of the interconducting capacitance with a difference of 1 pF / per meter linear, and in fact a huge step in the measurement of indicators (in this case, tens of pF of the passage of audio or video signals) people - listeners, music lovers and audiophiles hear a distinct difference in sound audio when comparing various connecting cables (interconnect and acoustic), and also distinguish the difference in the quality of the video image on the same monitor connected by different video cables.

The present invention is industrially applicable, as it can be implemented using technologies used in the manufacture of cables in the electrical industry.

Claims (4)

1. A conductive cable containing two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to contact nodes, characterized in that the insulating sheath is a tape with conductive conductors fixed along the edges of the insulating sheath cores located on the tape in the area between the contact nodes at a distance of at least 4 cm from each other, while the specified tape is made with the possibility of connecting its edges between the wallpaper for at least part of its length for the convergence of conductors. 2. A conductive cable containing two conductive conductors isolated from each other, placed in an insulating sheath, and the ends of which are connected to contact nodes, characterized in that to ensure regulation of the parameter of the conductive capacitance, conductive conductors located at a distance from each other on the site between the contact nodes, interconnected along the length of the lock type "lightning" to remove these wires from each other when unfastening the latter. 3. A conductive conductor containing two insulated conductors located in a common insulated sheath, characterized in that both conductors are twisted along the length of the conductive conductor in said sheath, wherein twisting is alternating twisting sections of equal length in a clockwise direction and counter-clockwise twisting portions having an equal number of turns in each twist. 4. Lived according to claim 3, characterized in that in each twist the conductors are twisted with the same twisting force.

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