SU1658426A1 - Method for outdoor lighting control - Google Patents

Abstract

This invention relates to electrical engineering. The purpose of the invention is to increase the reliability of work. A feature of the invention is the supply of voltage to the phase wires of the beginning of the next section of the cascade and their connection to the phase wires of the end of the previous section after the occurrence of voltage on one of the phase wires of the end of the previous section when the cascade is turned on, and the voltage of the beginning of the next phase is removed. of the cascade section and their disconnection from the phase conductors of the end of the previous section upon the occurrence of a current surge in said phase conductor with a forced decrease in its resistance relative to evogo wires when disable cascade yl 3

Description

The invention relates to electrical engineering.

The purpose of the invention is to increase the reliability of the outdoor lighting cascade.

Figure 1 presents a device that implements the method; Fig. 2 shows diagrams characterizing the operation of the device when the cascade of outdoor lighting is turned on and off; Fig. 3 shows the voltage & sections of the cascade in different modes of operation.

The device contains the first 1 and second 2 points of power. The output wires of the first 3 power source through the power contacts 4 of the first contactor are connected to the phase wires 5.1, 5.2, 5.3 of the first stage of the cascade. Light sources 7 are connected between these wires and the neutral wire 6. Wire 5.3 is control wire

The control cable 5 3 is connected via the opening auxiliary contact 8 of the first contactor and the low-resistance resistor 9 is connected to the neutral wire 6. The coil 10 of the first contactor is connected to the control device 11. The output terminals of the second power source 12 via the power contacts 13 of the second contactor are connected to the phase wires 14.1, 14.2, 14 3 in the second section of the cascade. Between the phase wires 14.1, 14 2, 14.3 and the neutral wire 6, the light sources 15 are connected. Wire 143 is a control wire second section of the cascade. The control wire 14.3 of the second section of the cascade is connected via the opening auxiliary contact 16 of the second contactor and the low-resistance resistor 17 is connected to the neutral wire 6. The different wires 51 52, 5.3 of the first section of the cascade are connected via wires 181,182 183 and force

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The left contacts 19 of the additional contactor are connected to the wires 14.1, 14.2, 14.3 at the beginning of the second section of the cascade. In wire 18.3 of the connection of wires 5.3 and 14.3 of the control, a current transformer 20 is installed, the secondary winding of which is connected to the current relay 21. The coil 22 of the second contactor is connected in the wire 18.3 and through the disconnecting auxiliary contact 23 of the current relay 21 to the neutral wire 6. The coil 24 of the auxiliary contactor is connected to the beginning of the control wire 5.3 and to the connection point of the coil 22 with contact 23.

A method for controlling an outdoor lighting cascade is implemented as follows.

When the outdoor lighting cascade is turned on at the time Ti from the control device 11, the voltage Uio is applied to the coil 10 of the first contactor (Fig. 2a). After the time ATi is triggered, the first contactor is supplied from its power contacts 4 to the phase voltage A.C. the first power source 3 to the phase wires 5.1, 5.2, 5.3. Auxiliary contact 8 opens. In the control wire 5.3, a voltage Uz is noted (Fig. 26). At the second power point 2, the voltage Uz is applied to the coil 22 of the second contactor. The current 122 flowing through the coil 22 provides, through time LT2, the operation of the second contactor and the closure of the power contacts 13 of this contactor. In this case, the wires 14.1, 14.2, 14.3 of the second section of the cascade are supplied with the voltage of phases A, B, C of the second power source 12. On the wire 14.3, the voltage Ui2 is shown (Fig. 2d). The voltage Ui2 also acts on the coil 24 of the additional contactor, causing the current Y to flow through this coil (Fig. 3g). The current S provides, in time dTz, the operation of the power contacts 19 of the additional contactor. When the contacts 19 are closed, the voltage of the phases A, B, C of the power source 12 is also applied to the wires 5.1, 5.2,5.3 of the end of the first section of the cascade. The magnitude of the voltage at the end of the wire 5.3 is determined in this case by the voltage Ui2 (Fig. 2e), the level of the phase voltage taken from terminal C of the power source 12.

Thus, when the first section of the voltage cascade of phases A, B, C is applied to the phase wires 5.1,5.2,5.3 of the power source 3 in the first section of the cascade having a length L, the voltage Uz is noted. equal to 1.05 UH at the beginning of the section and 0.95 Un at the end of the section (fig.Za). Connecting to the phase wires 5.1. 5.2, 5.3 the end of the first section of the cascade voltage Ui2 of the second power source 12 provides an increase in voltage at the end of the first section of the cascade to

values of 1.05 UH, while the voltage level over the entire length L of the first, section does not decrease below the nominal value UH (Fig. 36). When voltage is applied from terminal C of power source 12 to

0 phase wire 5.3, a load current flows through the current transformer 20. However, considering that the phase conductors of the first section of the cascade are supplied with voltage from two sources 3 and 12 of the power supply, the magnitude of the current

5 (Fig. 2g) passing through the primary winding of the current transformer 20 cannot exceed the rated current n load, i.e. I20 IH. Since the current relay 21 has a pickup setting for the current P above the maximum operating current of the first section of the cascade, neither when the voltage Uz is supplied from source 3 nor when the voltage U.p. of source 3 and Ui2 of power supply 12 is bi-directional not

5 may.

When the outdoor lighting cascade is disconnected at time Ta, the device

11, the voltage Uio is removed from the coil 10 of the first contactor (Fig. 2a), the power contacts 4 of which open, disconnecting the phase wires of the first section from terminals A, B, C of the first power source 3. In this case, the voltage 5.3 is removed from the wire 5.3 (as well as from the wires 5.1 and 5.2)

5 (fig.2b). The phase conductors of the first section of the cascade are supplied with voltage only from the second power source 12. The voltage distribution over the first section of the cascade corresponds to FIG. When eating

0 of the first stage of the cascade from the second power source 12, the current in the connection wire 18.3 increases. With increasing current I20 flowing through the primary winding of the current transformer 20, to the value of max

5 (Fig. 3) due to a decrease in the control phase resistance 5.3 when the contact 8 is closed and the resistor 9 connected to the phase wire 5.3 connected to the neutral wire 6 increases, the current in the coil 21 increases

0 relay. The relay 21 current through time ATB opens its contacts 23 and de-energizes the coil 22 of the second contactor and the coil 24 of the additional contactor. The power contacts 13 of the second contact disconnect the phase wires 14.1, 14.2, 14.3 of the second section of the cascade from terminals A, B, C of the second source

12pitani, and the power contacts 19 of an additional contactor disconnect the end of the first section of the cascade from the beginning of the second section of the cascade. Thus, the outdoor lighting cascade is reset.

Claims (1)

Invention Formula The method of controlling the cascade of external lighting, which means that when the cascade is turned on, voltage is applied to the phase wires of the beginning of the first stage of the cascade, control the voltage relative to the neutral wire of one of the phase wires at the end of each stage of the cascade and the current in the phase phase. When the voltage is applied, the voltage is applied to the phase conductors at the beginning of the next section of the cascade, and when the cascade is disconnected, the voltage is removed from the phase conductors at the beginning of the first section of the cascade, which differs in o, in order to increase the reliability in the operation of the cascade, they additionally control the voltage relative to the neutral wire to mentioned phase wire at the beginning of each stage of the cascade, except the first, and the current in this phase wire at the end of each stage of the cascade and in the presence of the mentioned voltage in the process of switching on the cascade connect the phase wires of the beginning of the next stage of the cascade and when disconnecting the cascade after removing the voltage from the phase conductors of each previous section of the cascade, by connecting a resistor, the resistance of the monitored phase wire relative to the neutral wire The appropriate stage portion and by increasing the current in said phase conductor is removed over a predetermined voltage from phase conductors beginning subsequent stage portion and off phase conductors beginning portion subsequent cascade phase conductors of the end portion of the previous stage.  h, i GCЈEfc U, i Uto AND YY J