UA8465U - Explosion-proof and flame-proof cable for three-phase power lines - Google Patents

Abstract

The proposed explosion-proof and flame-proof cable for three-phase power lines contains a core with at least three insulated power conductors, which are covered with a sheath and separated by layers of insulating material that fills gaps between the conductors, insulated control conductors and an earthing conductor, which are wound onto the core and covered with an inside protective sheath, an intermediate sheath, which is formed by winding a strip of fire-resistant material onto the inside protective sheath, and an outside protective sheath.

Description

Description of the invention

The proposed technical solution belongs to electrical engineering, in particular, to cable products, and is aimed at creating a new design of flexible power cables with explosion-fire safety parameters. Products of this purpose will be used in the coal industry and other branches of the national economy, where cable operation is carried out in conditions of an explosive environment.

During the operation of cables in mines, as a result of their damage, the following dangers arise: - electric shock; - fires due to the occurrence of leakage currents and short circuits; - an explosion of ore gas and coal dust due to a short circuit, break or short circuit in the leakage current circuit.

The first danger is eliminated by using devices to protect against electric shock, which are serially produced and have reliably proven themselves in operation. 19 It should be especially noted that with the introduction of shielded power cables in mines, the conditions for the occurrence of phase-to-phase short circuits are usually eliminated. This is explained by the fact that a short-circuit between the phases is preceded by a short-circuit of the phase to the ground, the danger of which is eliminated by the anticipatory disconnection of the cable from the network (before the occurrence of a short-circuit). This is an important decision to prevent the conditions for the formation of in the cable network.

In addition, devices of maximum current protection are used, which allow to reduce the time of development of short-circuit current.

The mentioned shows that the safety of spark formation is provided both by electrical protections in the power supply circuit and by the constructive protective parameters of the cable. Currently, seven-wire cables of the КГЗШ type, containing three main, three auxiliary and one grounding wire, are widely used in the industry. These wires are twisted around the grounding wire and enclosed in a protective single-layer sheath.

The disadvantages of these cables include: the use of a single-layer sheath, any damage to which 29 leads to a violation of the insulation of the current-carrying cores, which causes moisture to enter the cable and mechanical damage to the cores; the absence of a core in the cable increases the probability of damage to the cores and creates conditions for the occurrence of short-circuiting. between veins This is caused by the fact that in a cable without a core, the forces that act on the convex surface of the compressed cores are concentrated on a small area and this leads to a concentration of pressure and, therefore, to the crushing of the cores and their dangerous damage. at

A well-known mining combined flexible power cable of the type SVOYU Жх7ОнЗх161х16б-бх25ни1х10 ("o (manufacturer-plant KAVIO KI AOMO, Czech Republic), consisting of: three cores with a cross-section of 7Ω 2, which form the "first power supply system with a voltage of 11408; three cores with a cross-section of 1bmm?, forming the second power supply system with a voltage of 500 V; a protective wire with a cross section of 1 mm? (used in networks with a grounded and neutral); six control wires with a cross section of 2.5 mm?7, placed in a common sheath, and one grounding wire with a cross section of 10 mm, laid along the axis of the core.

The construction of the SVOI type cable is as follows: a core with a longitudinal hole in the middle is laid along the axis, in which a grounding wire with a cross section of 10 mm is laid, three power cores with a cross section of 7 Ohm are wound around this core and a twist of the control cores in the sheath, and in the end parts of the core rays, three power and one protective core with a section of 16 mm. On top of the scrotum, the inner and outer sheaths are successively applied. c The advantages of this cable should include: the presence of a double-layer sheath, which provides increased strength characteristics of the cable; increasing the mechanical strength of the cable due to the damping properties of the profiled core; reduction of mechanical stresses between the veins due to the distribution of the pressure of the main veins on a large area of the concave surface of the core. The latter increases the cable's resistance to crushing shaft and shock loads. At the same time, the well-known cable, designated as a prototype, has the following disadvantages: и" - use for insulation of cores and the inner shell of fire-hazardous materials. The sheath material is flame retardant, however, exposure of the cable to an open flame will cause the sheath and insulation to burn.

Me. lived to midi The latter will cause between phases; c 20 - insufficient flexibility of the cable due to the rigid connection of the inner and outer shells; - the materials from which the cable is made, as well as its construction, do not provide the parameters of explosion protection and fire resistance of the cable; - the adopted shape and dimensions of the profiled core do not take into account the number of cores in the cable. This leads to a decrease in the efficiency of using the core and a violation of the geometric stability of the veins of the second line

Electricity supply company; - asymmetric laying of the control cores relative to the main cores leads to the formation of the indicated E.R.S. in control circuits consisting of control and ground wires. The influence of the given e.r.s. causes self-activation of control circuits and, therefore, unauthorized switching on of machines (violation of the requirements of Clause 5.8.6 of the Rules of Safety in Coal Mines DNAOP 1.1.30-1.01.00 and Clause 2.8.19.3 "Regulations on the Safety of Slaughter Machines, Complexes and 60 Aggregates. Makiivka-Donbass, 1990").

The noted shortcomings indicate the need to create a cable with explosion-fire safety parameters, which, in addition, has increased operational characteristics.

The basis of a useful model is the task of creating such a cable, in which the introduction of an explosion-proof barrier into its structure and a special laying of a twist from the control and grounding wires allows to increase the safety of the use of the cable in explosive environments, in particular, mining of coal mines.

The task is solved due to the fact that an explosion-proof cable for three-phase power supply, containing at least three main cores wound on a core, twists of control cores in the sheath and a grounding core, which are located in the inner and outer protective sheaths, according to the useful model , equipped with a tape made of fire-resistant and flame-retardant material, located between the protective sheaths, a split grounding wire is inserted into the twist of the control wires, while the sheath of the twist is made of a semiconducting material and laid along the cable axis, and the core is made folded and formed by a round sheath that embraces twist, Y separators connecting to this shell, 7/0 VMounted in recesses between the main cores.

The results of experimental research conducted in Maknda proved that the explosion protection of cables can be provided according to the principle of slot (flange) explosion protection, as provided for in explosion-proof casings of electrical devices | see Kaimakov A.A., Torgashov V.S., Pesok S.A . etc. "Explosive safety of mining electrical equipment" Sub. ed. A.A. Kaimakova, Moscow, Nedra, 1982-2076.)

During the creation of the proposed cable, the following parameters of explosion protection were adopted: - gaps between the current-carrying cores, the core and the surface of the inner shell; - gaps between the explosion-proof barrier and the surfaces of the inner and outer shells; - the length of the output path of the products between surfaces forming a gap.

A feature of the cable design in terms of improving explosion protection is that relative to the arc that occurs between the cores, there is a screen, the function of which is performed by the inner sheath, and the cavity formed between the sheaths is an unloading device for red-hot copper particles and products of copper. The outer shell serves as a hermetic and mechanically strong device, which does not allow products to escape. into the surrounding explosive environment.

The special feature of the explosion protection of the proposed cable is that the explosion-proof barrier introduced between the sheaths extinguishes the flame and, in addition, it is made of fire-resistant, practically non-flammable material. The use of a barrier with such properties improves the explosion protection parameters of the cable. at,

The concept of creating a design of an explosion-proof flexible power cable is based on: - a mechanically strong cable design with the functions of diagnosing electrical and structural parameters; protective disconnection of the cable in case of abnormal external damage; у зо - localization of sparking at the place of cable damage; - placement of the main cores in the cable structure in such a way that the conditions for the formation of k. 3. are difficult; ix, - creating a design of the main wires, which takes into account the reduction of currents "Mr

In the declared technical solution, a new cable design with explosion-fire safety parameters and guaranteed mechanical strength is proposed. co

The explosion-fire safety parameters of the cable are provided with the help of the explosion-fire-proof barrier introduced into the cable design, which is a fire-resistant and flame-retardant tape, and which, together with the inner and outer sheaths, forms a slotted explosion protection. The physical and mechanical properties of the barrier ensure "flame extinguishment, temperature reduction and neutralization of fire products." main veins At the same time, the barrier creates a certain mobility of the specified shells among themselves and, thereby, increases the flexibility and strength characteristics of the Z 0 cable. c In the claimed cable, the core is folded and is a round shell, in which there is a twist of control and grounding wires, and separators connected to this shell. The latter were made in ;" in the form of profiled flexible rods made of elastic material, for example, polyvinyl chloride, the shape of which corresponds to the shape of the recesses between the main cores and the round shell of the secondary cores. This design of the core, in contrast to the known ones, allows to increase its damping properties and, in addition, achieves the given mobility of its component parts. The proposed design of the core for the first time provides protection against overload in case of excessive mechanical load acting on the cable due to the fact that the main cores with separators are "turned" around the circular sheath. b The grounding wire is split to achieve the correct general twisting of the wires.

The cable has a symmetrical and uniform laying of the main cores along the perimeter of the cable, and the control and grounding cores are made by general twisting, placed in a round shell, which is located along the cable axis.

Such solutions ensure: geometric stability and mobility of the cores in the cable, which increases its flexibility; the uniformity of the distribution of the mechanical load acting on the veins; improvement of damping

Han properties of the core, localization of inductive processes in the cable and elimination of their influence on control circuits.

In Fig. the design of the proposed cable is given.

The cable contains six main cores 1, which are formed by a copper wire, insulation 2 and a screen layer 3.

Twist 4 of the control 5 and grounding wires, placed in the round shell 7, is a control cable. The main cores 1 are wound on top of the round sheath 7. Flexible separators 8 are placed in the recesses between the main cores on the side of the sheath 7. The inner sheath 9, the explosion-fire-proof barrier 10, and the outer sheath 11 are successively placed on the twists of the main cores. The connectors of the round sheath 7 and flexible separators 8 form cores 12.

The explosion-proof barrier is made of fire-resistant tape, the basis of which is woven fiberglass threads with a flame-retardant material applied to it, for example, "OGRAKS". This tape is resistant to the action of both 65 open flames and high-temperature gases and hot metal particles.

The explosion-proof barrier is located between two shells and is placed on top of the inner shell 7 by winding the tape with or without overlap. Such a design simultaneously achieves: increasing the strength of the shell by ensuring the mobility of the outer shell relative to the inner one; formation of gap protection with explosion protection parameters (gap between the tape and shells; the length of the exit path of hot metal particles and gases); reduction of dynamic loads arising at k.3. between veins; fire extinguishing; lowering the heating temperature of the products of arc combustion and neutralization of the products This was confirmed by experimental studies conducted in Maknda.

In addition, with the help of such a barrier, for the first time, fire-resistant properties were achieved both under the action of k.z. in the cable in case of its damage, as well as in the case of the cable being in the area of an open flame. With an external 7/0 Influence of fire, the cable will remain undamaged for 2...3 hours, and in the case of fire sparks are not allowed to be emitted inside the outer shell 11.

The mechanical strength of the cable is achieved by increasing its flexibility, the geometric stability of the cores in the cable and reducing the mechanical stresses between the cores due to the damping properties of the shaft core 12.

The design of the core strengthens its elastic properties, which increases the resistance of the cable to shock and /5 crushing loads.

The use of a core, which performs the functions of a damping cushion, minimizes the possibility of the occurrence of c.z. between the veins and reduces the pressure on the main veins, as it is distributed over a large area of the concave surface of the heart; mechanical stresses are evenly distributed between the cores; the geometric stability of the cores in the cable and its resistance to crushing and shock loads are supported.

In the proposed cable, the main cores are split and thus each core consists of two separate wires. This solution achieves: uniform placement of cores along the cable perimeter; better filling of the cable structure; reducing the cross-section of each wire, which increases the flexibility of the cable as a whole; geometric stability of the cores in the cable, especially in combination with the core; complicating the conditions for the emergence of the regime of the former; decrease in current due to an increase in the resistance of each wire that makes up the main core, in ov Compared with the cross-section of one core of such a cross-section; increase in the current load on the core as a whole; - increase in electrical strength by reducing the thickness of the insulation.

Assuming a split design of the main cores and placing a twist of the control and grounding cores in the center of the main cores, the conditions for the formation of an additional source in the secondary circuits caused by the phenomenon of mutual induction are eliminated. Making the shell 7 from a semiconducting material allows you to create contact between the grounding wire and the screen layers of the main wires, which is required for the functioning of protection devices in case of non-normalized X-resistance, insulation of the main wires. "Mr

The explosion protection parameters of the proposed cable are provided by laying a fire-resistant tape between its inner and outer sheaths. As a result of the excess pressure that occurs inside the cable during a short circuit. as a rule, there is a breakthrough of the inner shell, which, in turn, extinguishes dynamic loads. Further, gases and heated particles under the action of elastic deformations of the outer shell will form gaps and paths for the spread of the specified products. along the fire-resistant and flame-resistant tape. Extinguishing and neutralization of the flame and products of the fire is taking place. veins, dynamic loads are reduced and, thereby, the danger of product release is eliminated. outside the outer shell, i.e. into the environment, which C 70 There may be a dangerous (explosive) concentration. c Mechanical protection against external and internal damage to the cable is determined by the stronger characteristics of the two-layer protective sheath, the core and the symmetrical packing of the cores in the cable. It has such properties;" the proposed cable design, which really allows to improve the mechanical and electrical strength of the cable and, therefore, to increase its safety properties and operational reliability.

It follows from the above that the proposed cable design fully corresponds to the one given earlier

Go! concepts of creating an intrinsically safe cable at the RV level. With the use of flexible power cables with explosion-fire safety parameters at the RV level, the problem of safe use of electrical energy in mines dangerous for gas and dust is solved for the first time. At this time, a test sample of explosion-proof cable (520 m) has been produced, the acceptance tests of which will be carried out in the 4th quarter of the current year. sl and a a. fi and

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Claims (1)

The formula of the invention - Explosion-proof cable for three-phase power supply, containing at least three main cores wound on the core, a twist of control cores in the sheath and a grounding core, which are located in the inner and outer protective sheaths, which is distinguished by the fact that it is equipped with a tape made of fire-resistant and flame-retardant of the material located between the protective sheaths, a split grounding wire is inserted into the twist of the control cores, while the sheath of the twist is made of a semiconducting material and laid along the cable axis, and the core is made folded and formed by a round sheath that embraces the twist and separators that connect with this sheath mounted in the recesses between the main veins. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2005, M 8, 15.08.2005. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. that 2 iv) then that « (ee) . and? (ee) sh» (o) sl So 60 b5