RU25367U1 - SINGLE-PHASE INSULATING TRANSFORMER FOR AERODROME LIGHT-SIGNAL SYSTEMS - Google Patents

Description

2002114149

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SINGLE-PHASE INSULATING TRANSFORMER FOR AERODROME LIGHT-SIGNAL SYSTEMS

The useful model relates to electrical engineering, in particular, to electric induction devices, and can be used in single-phase insulating transformers operating in electric circuits with series power supply to consumers, namely in aerodrome light-signal systems.

Known single-phase isolation transformers, which are currently used in light-signal systems of civil aerodromes of the Russian Federation, are made, as a rule, of the same type, namely, in the form of a toroidal magnetic circuit with primary and secondary windings. Light-signal systems contain several (up to 50) cable rings (garlands), each of which is a high-voltage electric circuit of up to 5 kilovolts, consisting of lamps (lights in the assembly), up to 100 lamps in a ring, isolation transformers and a dimmer, which maintains a stable current in the circuit in accordance with the set brightness level. In each cable ring, the primary windings of all isolation transformers are interconnected in series and connected to a dimmer, and the secondary windings of isolation transformers as power sources are connected to lamps (Yu.S. Basov. Lighting devices, Moscow, Transport, 1993).

A feature of the operation of isolation transformers is the IR supply with a stable current, which does not change depending on the presence or absence of a load on the secondary winding of the transformer. Therefore, in the event of a load break, for example, when a lamp burns out (idle mode), electromagnetic induction in the magnetic circuit

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reaches a large value, and saturation occurs in the magnetic circuit. Saturation results in distortion of the sinusoidal current shape in the primary winding and a corresponding expansion of its frequency spectrum, which leads to a sharp increase in hysteresis losses in the transformer magnetic circuit and, therefore, to its heating and accelerated aging of the transformer insulation.

In addition, an isolating transformer operating in idle mode introduces a significant additional inductance into the cable ring. When each subsequent lamp burns out, the inductive resistance of the cable ring increases, and the equivalent active resistance of the cable ring decreases. Due to a change in the ratio between the active and inductive resistances, the power factor decreases, therefore, to maintain the effective current value that provides the necessary brightness of the remaining lamps of the landing lights, the voltage at the clamps of the cable ring is increased. This leads to an increase in the probability of breakdown of the ring elements.

In addition, the distortion of the sinusoidal shape of the current in the transformer windings in the no-load mode results in a corresponding voltage distortion on the secondary winding, and the value of the shape factor can be significantly greater than unity. The amplitude of the open circuit voltage on the secondary winding of isolation transformers can reach two hundred to three hundred volts, and in the pulse (at the time of breaking the lamp thread) up to one and a half thousand volts, as a result of which the probability of insulation breakdown of the primary and secondary transformer windings increases sharply.

Since burned out lamps in the lights of light-signal systems are replaced only when the airport is closed, i.e. no more than once a day, then isolation transformers can be in idle mode for a sufficiently long time, which creates conditions for significant overheating of the magnetic cores and accelerated aging of the insulation, as well as

increase the likelihood of breakdown of cable ring elements and isolation of the primary and secondary windings of the transformer.

A disadvantage of the known isolation transformers is their low reliability and low service life, as well as the increased likelihood of breakdown of the elements of the cable ring in which the isolation transformer operates.

The closest set of essential features to the utility model is a single-phase isolating transformer for aerodrome lighting systems containing a toroidal magnetic circuit on which successively alternating layers are installed: insulation, primary winding, insulation, secondary winding and insulation. The nervous winding is connected to a dimmer, which is a source of stable current. The secondary winding is connected to the consumer: the lamp of the fire of the airfield light-signal system (Transformers isolators for the YOT series Technical description and operating instructions, BTLI.670111.006, 1984, sheet 6.7, section 3).

A disadvantage of the known isolation transformer is its low reliability and low service life due to heating of the magnetic circuit and accelerated aging of the insulation. This is because the isolation transformer is supplied with a stable current, which does not change depending on the presence or absence of a load on the secondary winding of the transformer, therefore, in idle mode

electromagnetic induction in the magnetic circuit reaches a large value, and saturation occurs in the magnetic circuit. Saturation results in distortion of the sinusoidal current shape in the primary winding and a corresponding expansion of its frequency spectrum, which leads to a sharp increase in hysteresis losses in the transformer magnetic circuit and, therefore, to its heating. Since the toroidal drain is difficult for a toroidal magnetic circuit with a multilayer winding, its heating continues

BEFORE reaching critical temperatures leading to accelerated aging of the insulation.

In addition, the increased likelihood of a breakdown in the insulation of the primary and secondary windings of the transformer in the event of a lamp burnout also leads to a decrease in its reliability and a decrease in the service life. The probability of breakdown of the windings is explained by the distortion of the sinusoidal shape of the current in them and the corresponding distortion of the voltage on the secondary winding, and the shape factor in the event of a lamp burnout can be significantly larger than unity.

In addition, a disadvantage of the known insulating transformer is the increased likelihood of breakdown of the elements of the cable ring in case of burnout of one of the lamps. This is explained by the need to increase the voltage at the clamps of the cable ring to maintain an effective current value that provides the necessary brightness of the remaining lamps of the landing lights, due to a significant increase in inductance in the primary circuit of the transformer.

The objective of this utility model is to create a single-phase isolation transformer for aerodrome lighting systems, which has high reliability and an increased service life, and also provides cable ring elements without breakdown in idle mode, and in the loaded mode, the necessary power is taken from the circuit, which maintains a relatively large current value (8.3 A for the highest brightness level) without increasing the physical dimensions of the magnetic circuit. The latter is explained by the fact that in order to provide the required output power, isolating 1e transformers for aerodrome lighting systems must have a significant number of turns in the primary winding, as a result of which the number of ampere turns increases to a value that causes deep saturation

FOR insulating transformers operating in aerodrome lighting systems, the centerline of the magnetic circuit should be increased several times.

The technical result of this utility model is to reduce electromagnetic induction in idle mode, as well as in loaded mode, but at the same time maintaining the necessary power on the secondary winding due to an increase in magnetic flux in the central core of the magnetocircuit.

electromagnetic induction is the reduction of magnetic saturation and hysteresis losses in the magnetic circuit.

The specified technical result is achieved in that in a single-phase insulating transformer containing a magnetic circuit with primary and secondary windings, the magnetic circuit is made of three rods, while the secondary winding is installed on the central rod, and the primary winding contains two sections that are mounted on peripheral rods and interconnected in series or in parallel.

In addition, the central rod is made with a cross-sectional area larger than the cross-sectional area of the peripheral rod.

In addition, the cores of the magnetic circuit are made of at least two parts.

The implementation of the magnetic core is three-core, and the primary winding of two sections, which are located on the peripheral rods, allows to halve the number of ampere turns exciting the electromagnetic field in each peripheral rod, which leads to a decrease in tension and, consequently, to a decrease in electromagnetic induction in the magnetic circuit.

The connection of the sections of the primary winding in series or in parallel ensures that partial magnetic fluxes of one direction are obtained in the central rod, which allows an increased magnetic flux due to the addition of partial fluxes and that

leads to obtaining in the loaded mode the necessary output power in the secondary winding with reduced electromagnetic induction.

In addition, since part of the magnetic flux generated by one of the sections of the primary winding branches into the opposite peripheral rod of the three-core magnetic circuit, the branched flux, being directed towards the magnetic flux generated by the second section of the primary winding, further reduces the electromagnetic induction in the peripheral rods of the three-core magnetic circuit.

The establishment of sections of the primary winding on different rods (the yokes of the magnetic circuit are free from the windings) allows teshoot directly from the magnetic circuit. In addition, the establishment of the primary and secondary windings on different rods of the magnetic circuit can improve the characteristics of winding insulation, as well as increase resistance to winding breakdown.

The implementation of the Central rod with a cross-sectional area increased in comparison with the peripheral rods, leads to an additional decrease in electromagnetic induction.

The implementation of the cores of the magnetic circuit compound, at least in two parts, can improve the manufacturability of the manufacture of the transformer.

The essence of the utility model is illustrated by drawings, where in FIG. 1 is an electrical diagram of a single-phase isolation transformer with series connection of sections of the primary winding, and FIG. 2 shows an electrical diagram of a single-phase isolation transformer with parallel connection of sections of the primary winding.

the central core 4 of the magnetic circuit 1. The primary winding 2 contains two sections 5, 6, which are made the same. Section 5 of the primary winding 2 is installed on the peripheral rod 7 of the magnetic circuit 1, and section 6 of the primary winding 2 is installed on the peripheral rod 8 of the magnetic circuit 1. Magnetic circuit 1 can be made of split tape magnetic circuits like PLV, SLO or the like, made of steel with low losses. The rods 4, 7, 8 can be made of at least two parts. Sections 5, 6 of the primary winding 2 are interconnected with the possibility of the formation in the central shaft 4 of magnetic fluxes of the same direction, while sections 5, 6 can be interconnected in series (Fig. 1) or in parallel (Fig. 2). The Central rod 4 can be made with a cross-sectional area greater than the cross-sectional area of the peripheral rod 7, 8, for example, 2 times, when the magnetic core 1 is made of two O-shaped rod magnetic cores. The secondary winding 3 is connected to a lamp (not shown in the drawing), and the primary winding is a 2nd power source (brightness control - not shown in the drawing).

Single-phase isolation transformer operates as follows.

In idle mode, when the current flows through section 5 of the primary winding 2 in the peripheral rod 7, an electromagnetic field with a magnetic flux arises, which branches into partial magnetic fluxes: to the central rod 4 and to the peripheral rod 8. When current flows through section 6 of the primary winding 2 an electromagnetic field with a magnetic flux arises in the peripheral rod 8, which branches into partial flows: into the central rod 4 and into the peripheral rod 7. In this case, partial magnets in the central rod 4 tnye flows from electromagnetic fields produced by the sections 5 and 6 of the primary winding 2, in the peripheral rods 7, 8 in the same direction, which ensures their sum, i.e., increase in value

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magnetic flux. In the peripheral rod 7, the partial magnetic flux generated by section 6 of the primary winding 2 when current flows through it is subtracted from the magnetic flux generated by section 5 of the primary winding 2, which reduces the magnetic flux and magnetic induction in the peripheral rod 7 and in yokes connecting rod 7 with a central rod 4. In the peripheral rod 8, the partial magnetic flux generated by section 5 of the primary winding 2 when current flows through it is subtracted from the magnetic flux generated by section 6 of the primary coils 2, which leads to a decrease in magnetic flux and magnetic induction in the peripheral rod 8 and in the yokes connecting the rod 8 to the central rod 4. A decrease in magnetic induction in the rods 7 and 8 and in the yokes of the magnetic circuit 1 leads to a decrease in the inductance of the primary winding 2 and reduction of hysteresis losses.

Under the action of a magnetic flux flowing through the central rod 4, an EMF is induced in the secondary winding 3, the magnitude of which is proportional to the sum of the partial magnetic fluxes from sections 5 and 6 of the primary winding 2. When the load is connected to the terminals of the secondary winding 3, a current begins to flow through the circuit, and a central rod 4 creates a magnetic flux branching into two partial magnetic fluxes, one of which branches into a peripheral rod 7, and the second into a peripheral rod 8. Partial magnetic fluxes are created the current of the secondary winding 3, in accordance with the Lenz law directed towards the magnetic flux generated by sections 5 and 6 of the primary winding 2, which reduces the magnetic flux in the magnetic circuit 1. Under the influence of the partial magnetic flux generated by the secondary winding 3 in the peripheral rod 7, in section 5 of the primary winding 2 induces an EMF that is opposite in phase to the voltage drop created in this section by the current flowing through the primary winding 2, which leads to a decrease in voltage drop by

section 5 of the primary winding 2. Under the influence of the partial magnetic flux generated by the secondary winding 3 in the peripheral rod 8 in section 6 of the primary winding 2, an EMF is induced, which is opposite in phase to the voltage drop created by the current flowing through the primary winding in this section, which leads to a decrease the voltage drop across section 6 of the primary winding 2. As a result, the total voltage drop across the primary winding 2 is reduced in comparison with the idling mode.

Provided that the same number of turns of the primary windings, the same current in them, and the same cross-section of the magnetic circuits of a known single-phase insulating transformer with a toroidal

magnetic circuit and the claimed single-phase insulating three-core transformer:

- the magnetic field strength in the magnetic core of a three-rod transformer is less than that of a toroidal transformer, since in each of the peripheral rods this field is created only by the primary winding section. The magnetic field strength in the central rod can be set by selecting its cross-sectional area. For example, when performing a magnetic circuit of two tape O-shaped cores (such as PL, PLV or similar), the tension is the same as in the peripheral rods. This leads to a corresponding reduction in hysteresis losses arising in the idle mode when the primary winding is supplied with a stable current. The magnetic flux, which induces the EMF in the secondary winding of the central rod, being proportional to its cross-sectional area, turns out to be the same magnitude as that of the compared toroidal transformer.

-Each winding of the secondary winding of the toroidal transformer interacts with the alternating magnetic field of the magnetic circuit, passing through the hole in the magnetic circuit, only once, while for a three-rod transformer - twice. As a result, the required number of turns of the secondary winding is half that of a transformer. at the three-rod transformer at the compared toroidal

Claims (3)

1. A single-phase insulating transformer for aerodrome lighting systems, containing a magnetic circuit with primary and secondary windings, characterized in that the magnetic circuit is made of three rods, while the secondary winding is installed on the central rod, and the primary winding contains two sections that are mounted on peripheral rods and connected between themselves in series or in parallel.  2. The transformer according to claim 1, characterized in that the central rod is made with a cross-sectional area greater than the cross-sectional area of the peripheral rod. 3. The transformer according to claim 1 or 2, characterized in that the cores of the magnetic circuit are made of at least two parts.