SU725278A2 - Device for power supply of three-phase gas discharge tube - Google Patents

Description

Each is connected to one of the main electrodes of the lamp, located through one, and the third one - to the second extreme main electrode of the lamp.

Three inductive ballast elements are magnetically coupled, two of which are connected to one of the main electrodes of the lamp, located between the extreme main electrodes, and the third to one of the extreme main electrodes of the lamp. All four inductive elements are magnetically interconnected.

In order to improve the re-ignition conditions and increase the stability of the lamp operating in the winding device of two magnetically connected ballast elements connected to the main electrodes of the lamp, located one through, are included according to the coupling coefficient between them, close to unity, and the third winding of the magnetically coupled the ballast element connected to the second extreme main electrode of the lamp is connected in accordance with the winding of the magnetically connected ballast element connected to the first extreme main electrode l mpy, and the coefficients communication between said third winding magnetically bound ballast element and the other two windings magnetically coupled ballast

elements lie in the range from g to 1.0.

at 3

Fig. 1 shows the principle electrical circuit of the first embodiment of the device; in fig. 2 - the same, equivalent circuit; in fig. 3 is a circuit diagram of a second variant of the device; in fig. 4 is a circuit diagram of a third embodiment of the device; in fig. 5 - a circuit diagram of the fourth variant; in fig. 6 - the same, equivalent circuit; in fig. 7 is a circuit diagram of a fifth embodiment of the device.

The device contains a gas discharge lamp 1 with four main electrodes, two of which 2 and 3 are located at opposite ends of the lamp, and two others 4 and 5 between them.

The power supply of the lamp is dried from a three-phase three-wire network through four inductive ballasts 6-9, the power of the extreme main electrodes of lamp 2 and 3 being dried through the corresponding two inductive ballast elements 6 and 7, the common point of which is connected to one From the phases of the network, and the electrodes 4 and 5 are supplied via the corresponding inductive ballast element 8 or 9 from the corresponding of the other phases of the string.

In the embodiment of the device shown in FIG. 1, magnetically coupled elements 6 and. In this embodiment, the device is achieved

the most complete balancing at the half magnetic connection (the coupling coefficient is close to 1.0) of elements 6 and y.

the windings of the magnetically connected 5 ballast elements are connected in accordance with, and their own inductive resistances are the same.

(End inductive resistances of two other Oallast elements 7 and a,

10, which do not have magnetic coupling, are also equal between soooi, each of them with the value of co-inductive impedance twice as large as each of the magnetically connected ballast elements, with a qv15 diagram of such an arrangement (see Fig. Z) represents an offset star-delta connection, the equivalent inductive resistances iU in the rays of the star and in the arms of the three gons are the same in magnitude, the camber gaps of the lamp in FIG. 2 are presented in the form of equivalent resistances 11.

25 In embodiments of the device shown in FIG. a and 4, oomogki of both parmagnetically bound ballast elements are included respectively and counter respectively.

About a device with three inductively coupled ollasts, shown in FIG. o, various options are possible, characterized by a set of magnetically coupled inductive ballast elements 6, 7 and 9 and the polarity of their windings.

5 In all the embodiments of this device, the objective of the invention can be achieved with different magnitudes of coupling coefficients between the windings of three magnetically coupled inductive ballast elements, which can be spaced, for example, on a common magnetic core of a double-rod or three-rod design.

These examples of the implementation of this version of the proposed device can vary in the consumption of materials for their manufacture, as well as the conditions for re-ignition and the stability of the discharge

lamp spans oh

These conditions are optimal when the inductive ballast elements 6 and 9 (Fig. 5) are turned on according to have a full magnetic coupling (the coupling coefficient is close to

5 1.0) and equal inductance of their own. The inductive ballast element 7 is connected in accordance with the inductive ballast element 6, it has a greater intrinsic inductance,

0 than each of the other two magnetically connected ballast elements, and equal coupling coefficients with them, with the magnitude of the coupling coefficient being greater — and

Y 3

less than 1.0.

The fourth inductive, ballast element 8 (Fig. 5), not magically related to the other three, decides on optimal conditions when its iliductive resistance is less than the intrinsic inductive resistance of the three other ballast elements.

The diagram shown in FIG. 5, the polarity of the connection of the windings is indicated when three magnetically coupled INDUCTIVE ballast elements are located on a common magnetic core of a double-rod structure.

An equivalent circuit of this variant of the device, made according to the scheme of FIG. 5 is shown in FIG. 6, and represents a star-delta connection, the equivalent inductive resistances 12 in the arms of the triangle being the same in magnitude. Equivalent reactances 13 in the rays of "stars" are also of equal magnitude, with smaller ones. The discharge intervals of the lamp in FIG. 6 are presented in the form of equivalent resistances 14.

This version of the device significantly improves the conditions for re-ignition and increases the stability of the operation of three-phase gas discharge lamps in comparison with the conditions of operation of single-phase lamps in general electrical power supply circuits. In this connection, it is possible to increase the ratio of the voltage on a single bit Gap of a three-phase lamp to a linear voltage of a three-phase network up to 0.95, which allows to significantly reduce the consumption of materials for the manufacture of the device and increase its efficiency.

A variant of the device is possible — when three inductive ballast elements are magnetically connected, two of which are connected to one of the main electrodes of the lamp, located between the extreme main electrodes, and the third one to ONE of the main main electrodes of the lamp. The device in this embodiment can be implemented in many ways, distinguished by the imis set of magnetically coupled inductive ballast elements 7, 8, 9, the polarity of connecting their windings, the coupling coefficients between them, and the design of the magnetic circuit, on which the windings of inductive ballast elements.

The optimal conditions for re-ignition and stability of the discharge intervals of the lamp will have the option of this device shown in FIG. 7, in which two of the three magnetically coupled inductive ballast elements connected to the main electrodes of the lamp, located through one (7 and 8 of FIG. 7), are connected in opposite directions and have a full magnetic coupling (the coupling coefficient is close to 1.0).

. A third magnetically coupled inductive ballast element 9 connected to one of the main electrodes of the LAMCs, located between the outermost 5 electrodes, is connected opposite to the magnetically coupled inductive ballast element 7 connected to the adjacent extreme main electrode of the lamp and has equal coupling factors with two other M1I magnetically bound ballast elements, and the magnitude of the coefficient

The bond is larger and less than 1.0.

/ 2

The diagram in FIG. 7, the polarity of the connection of the windings is indicated when the windings of the three magnetic-coupled inductive ballast elements are located on the common magnetic core of the double-rod structure. The equivalent circuit of this device is similar to that shown in FIG. b.

The optimal variant of the device shown in FIG. 7, will require several

with a lower consumption of materials for production than the optimal variant of the device, realized according to the scheme shown in FIG. 5. Another device variant is possible.

0 characterized in that all four inductive ballast elements are magnetically coupled to each other.

The magnetic coupling between the inductive ballast elements of the device can be accomplished by placing the corresponding windings of the ballast elements on a common magnetic conduit, for example, two-, three- or four-rod design, or using the communication windings when placing the windings of the inductive ballast elements as a common, and on separate magnetic circuits.

Variants of the device were tested on four-electrode mercury lamps

5 high pressure power from 200 W to 6000 W and showed their high efficiency.

The studies confirmed that the load of the three-phase three-wire network in all tested versions of the device was symmetrical, both during start-up and during operation of three-phase high-pressure mercury lamps, and the pulsations of the luminous flux were 4-7%, which does not exceed

5 pulsations of the luminous flux of incandescent lamps and 10-15 times less than pulsations of the luminous flux of single-phase lamps of the same type.

60

Claims (8)

1. Device for three-phase power supply gas discharge lamp on auth. St. No. 570226, characterized in that in order to provide load balancing of the three-phase three-wire network in the starting and operating modes, balancing the lamp currents and reducing the pulsation of the lamp's luminous flux, all four ballast elements of the device are inductive in nature and at least two of them are magnetically connected. 2. A device of claim 1, characterized in that, in order to provide the most complete load-balancing of a three-phase three-wire network and lamp currents, two inductive ballast elements connected magnetically to the main electrodes of the lamp are located through one, and the windings are magnetically connected The ballast elements are included according to, and the coupling coefficient between them is close to 1.0. 3. The device for and. 1, characterized in that, in order to ensure the most complete balancing of the network load and lamp currents, inductive ballast elements connected to the main electrodes of the lamp through one are magnetically connected in pairs, with the windings of both pairs of magnetically connected ballast elements g -included according to. 4. The device according to claim 1, characterized in that, in order to ensure the most complete load balancing of the network and lamp currents, each of the two inductive ballast elements connected to one of the extreme main electrodes of the lamp is separately connected in pairs with the inductive ballast G cell connected to the corresponding adjacent main electrode of the lamp, with the windings of both pairs of magnetically connected ballast elements connected in opposite directions. 5. The device according to claim 1, characterized in that, in order to provide a more complete load balancing of the network and lamp currents, three inductive ballast elements are magnetically coupled, two of which are connected each to one of the main lamp electrodes arranged through one and the third is to the second extreme main electrode of the lamp. 6. The device according to claim 1, characterized in that, in order to ensure the most complete balancing of the loads of the network and lamp currents, three inductive ballast elements are coupled, two of which are connected to one of the main electrodes of the lamp, located between the extreme main electrodes, and the third - to one of the extreme electrodes of the lamp. 7. A device according to claim I, characterized in that, in order to ensure the most complete load balancing of the network and lamp currents, all four inductive ballast elements are magnetically interconnected. 8. The device according to claim 5, characterized in that, in order to improve the conditions for re-ignition and increase the stability of the lamp, the windings of two magnetically connected ballast elements connected to the main electrodes of the lamp located through one are connected according to zi-nimp close to one, and the winding of the third magnetically connected ballast element connected to the second extreme main electrode of the lamp is connected according to the winding of the magnetically connected ballast element connected to the first extreme th main lamp electrode, and the coefficients communication between said third winding magnetically bound ballast element and the other two windings magnetically coupled ballast elements lie in the range of from T7 to LO. w eleven Rig.- /