SU1136256A1 - System for control and check of three-phase exterior lighting systems with cascade connection - Google Patents

Abstract

CONTROL AND MONITORING SYSTEM OF THREE-PHASE NETWORKS OF EXTERNAL LIGHTING WITH CASCADE SWITCHING, containing actuating points of each section of the illumination line, the coil of the contactor of the first lighting of which is connected by a communication line with the control point, and the short circuit of the control coils of the contactors; the illumination line is connected by control wires with leads for connecting to the phase and j neutral wires of the previous part of the illumination line; The first point of the I light sections has a terminal for connection to the neutral supply wire; a network which in each of the executive points, except for the first one, is connected to a terminal for connection to the neutral network of the previous part of the lighting line, which is the purpose of reducing the time for determining 1C;: 6L31A1:. -A iHO- l, t - ;. I: viAI W "11MSHA faults in the outdoor lighting network, the executive points of each section of the lighting line are equipped with a power supply voltage monitoring unit, the first and second lighting voltage monitoring units, the control unit the current of the lighting line section, the voltage pulse sensor of the lighting line section, the current pulse sensor of the lighting line section, the encoder, the character analyzer, the switch, the control relay, the coil of which is connected parallel to the lighting turn-on contactor coil, the input of the character analyzer is connected to the switch output, the first input (L switch is connected to the first switching contact of the lighting-switching contactor, the closing group of which is connected to the output of the current pulse sensor of the lighting line section, and the switching output to the sensor output eg:; the illumination line, the second input of the switch is connected to the output of the encoder by a two-wire line, one of whose wires is connected to the output: l for the connection to the zero pro0: mains water, the first input is the cipher the controller is connected to the first switching contact of the control relay, the disconnecting group of which is connected to the output of the power supply control unit, and the closing one to the output of the first voltage control unit of the lighting line section, the second input of the encoder is connected to the second switching contact of the lighting contactor

Description

The closing group of which is connected to the output of the current control unit of the lighting line section, and the breaker to the output of the second voltage monitoring unit of the lighting line section, the first and second inputs of the encoder are connected to the first and second control inputs of the switch, the control point is equipped with a current relay, connected to the communication line, a relay trigger, two time pulse converters and two pulse counters, the input of each of which is connected to the first and second outputs after the corresponding time rows trigger relay, actuating point of the first portion of illumination line is further provided with a resistor connected to the communication line, the delay element output

which is connected parallel to the specified resistor, and the input is connected to the character analyzer, each performer: SRI point of the lighting line sections, except the first one, is additionally equipped with a terminal for connecting to the supply mains phase conductor and AC switches connected between the control phase conductor and the second switching contact of the relay control, the closing group of which is connected to the control neutral wire, and the breaker group to the output for connection to the phase conductor of the supply mains, while the control input of the switch current is connected to the output of the character analyzer of the executive point of the corresponding part of the line of illumination,

The invention relates to electrical engineering, in particular, to device circuits for providing remote control and indication of operating modes of the AC network, and can be used in automatic control and monitoring systems for outdoor lighting networks with cascade activation. The control and monitoring systems of the lighting network with cascade connection of the lighting line sections are known, which contain a control point connected to the executive point of the communication line. Turning on the outdoor lighting cascade in this case is carried out by supplying Tojca control to the communication line, which causes the operation of the intermediate relay, which turns on the control circuit of the lighting turn-on contactor at the operating point lj. The inclusion of lighting installations in this way does not allow the control of the inclusion of a cascade which is a negative factor in the known solution. The closest to the invention of the technical essence and the achieved result is the control system. The external lighting installations contain the actuating points of each section of the lighting line, the contactor coil of the first lighting of which is connected to the control point, and each of the coils of the lighting contactors is connected by leads to the control points of the subsequent lighting line sections. the phase and neutral wires of the network of the previous section of the lighting line, each actuating point of the lighting line sections having an output for connecting tim to the neutral conductor mains, wherein each of the actuators claims, except the first, is connected to a terminal for connection to the neutral conductor network portion of the previous line illumination iZ. A known system is designed to control and monitor a network of outdoor lighting with cascade switching-on sections of the lighting line. The control of switching on the cascade, determined by the sequence of switching on the contactors of the evening and night lighting, makes it possible to evaluate the operability of the outdoor lighting cascade as a whole and makes it impossible to determine the specific place of the cascade malfunction, i.e. damaged part of the lighting line. Considering that outdoor lighting cascades contain up to 15 sections of the lighting line to identify a faulty section of the lighting line when applying a known control and monitoring system by means of detours or bypassing the cascade, it is necessary to spend a considerable amount of time, which leads to a lot of material damage. Thus, the control of the outdoor lighting cascade with known control and monitoring systems is accompanied by significant losses of time for determining the faulty section of the line, lighting in the cascade. The purpose of the invention is to reduce the time it takes to detect faults in the outdoor lighting network. The goal is achieved in those in the control and monitoring system of three-phase networks of outdoor lighting with cascade connection, containing executive points of each section of the line of lighting, the coil of the contactor of turning on the lighting of the first of which is connected to the control point, and each of the coils of the contactors of turning on the illumination of the executive points of the subsequent sections of the line of illumination is connected with control wires to the leads for connection to the phase and zero wires of the previous section of the line of illumination, Each of the executive points of the illumination line sections has an output for connecting to the zero wire of the supply mains, which in each of the executive points, except the first one, is connected to a terminal for connecting to the zero wire of the network of the preceding lighting line section, the executive points of each illumination line section are supplied power supply control unit, the first and second power supply voltage control units of the lighting line section, the current control unit of the lighting line section, the voltage pulses of the section escheni a portion of the current pulse sensor line illumination. encoder, character analyzer, switch, control relay, the coil of which is connected in parallel to the coil of the lighting contactor, the input of the character analyzer is connected to the switch output, the first input of the switch is connected to the first switching contact of the lighting contactor, the closure group of which is connected to the output current pulse sensor of the section the lighting line and the disconnecting line to the voltage sensor output of a part of the lighting line, the second input of the switch is connected to the output of the encoder two-way the first line of the encoder is connected to the first switching contact of the control relay, the disconnecting group of which is connected to the output of the power supply control unit, and the closing one to the output of the first control unit the voltage of the lighting line section, the second input of the encoder is connected to the second switching contact of the lighting activation contactor, the closure of which is connected to the output of the current section control unit lighting, and disconnecting to the output of the second block controlling the voltage of a section of the lighting line, the first and second inputs of the cipherto connection to the first and BTOpbw control inputs of the switch, the control point is equipped with a current relay connected to the communication line, a relay trigger, two pulse times converters and two pulse counters, the input of each of which is connected to the first and second outputs of the relay trigger through the correspondence of the time, the executive point of the first section of the lighting line is added is supplied with a resistor included in the communication line, a delay element whose output is connected parallel to the specified resistor, and an input to the character analyzer, each executive point of the lighting line sections, except the first one, is additionally equipped with a output for connecting to the mains phase wire and AC switches connected between the phase conductor of the control element and VTOR1L4 the switching contact of the control relay, the zamhanzhtsa group of which is connected to the neutral control wire, and the disconnecting group is connected to the terminal for Connected to the phase conductor of the power supply network, while the control input of the alternating current key is connected to the output of the character analyzer of the control point of the corresponding part of the illumination line.

. Fig. 1 shows a diagram of a control and monitoring system for three-phase networks of narcid lighting with cascade connection; Fig. 2 is a diagram of power supply voltage monitoring units in Fig. 3 is a diagram of voltage control units and current sections of the lighting line and voltage pulse sensors and currents i in Fig. 4 is a diagram of the encoder j in Fig. 5; figure 6 - diagram analyzer signs; in Fig.7 diagram of the delay element; Fig. 8 is a diagram of the AC key; Fig. 9 is a diagram of a control point; Fig. 10 is a graphic representation of the transmission of information through an outdoor lighting cascade. I

The control and monitoring system for phase networks of outdoor lighting with cascade switching on (Fig. 1) contains a control point 1 connected by a communication line 2 with an operating point 3. A connection 4 of the lighting contactor 5 is connected to the communication line 2 at the execution point 3 between the mains 6 and the first section 7 of the illumination line. The illumination line section 7 has pins 8, to which the phase and neutral control wires 9 are connected, connected to the coil 10 of the contactor 11 to turn on the lighting 11 at the actuating station 12. The contactor 11 connects the power supply network 13 to the section 14 of the lighting line 14, named conclusions 15 to which the wires 16 are connected to the control unit 17 which connects the supply network 1. with section 19 of the lighting line

Executive item 3 contains a power supply voltage monitoring unit 20 connected to the phase conductors ABC of the power supply network 6, as well as the first lighting control unit voltage control unit 21 connected to section 7 of the lighting line

the second unit 22 monitors the voltage of the illumination line portion, the unit 23 monitors the current of the illumination line portion, sensor 24 pulses the voltage of the illumination line portion and sensor 25 pulses the current of the illumination line portion. In parallel with the light switch 4 contactor coil 4, a control relay 26 is connected.

Executive item 3 contains an encoder 27, the first input of which is connected to the first switching contact 28 of the control relay 26, the disconnecting group of which is connected to the output of the supply voltage control unit 20, and the closing group is connected to the output of the first lighting line section 21 control unit.

The second input of the encoder is connected to the first nepeKjno4aiM4eMy contact 29 of the lighting enable contactor 5, the disconnecting group of which is connected to the output of the second lighting linrsh section of the voltage control unit, and the closing group is connected to the output of the lighting line section current control unit 23. The output of the encoder is connected to the first input of the switch 30.1 by a two-wire line, one of the wires of which is connected to the pin 31 connected to the neutral wire of the supply network. The second input of the switch 3 is connected to the second switching contact 32 of the lighting turning contactor 5, the disconnecting group of which is connected to the output of the sensor 24 of the supply voltage pulses, and the closing group is connected to the sensor 25 of the current line section of the lighting line. The control input of the switch is connected to the first and second inputs of the encoder 27, and the output of the switch 30.1 is connected to the input of the analyzer 33. The bypass sign of the analyzer 33 characters is connected to the input of the delay element 34. The output of the delay element is connected to a resistor 35 connected to the link 2.

Executive item 12 contains a power supply voltage monitoring unit 36, connected to the phase conductors ABC of the power supply network 13, as well as the first voltage control unit 37 connected to the .14 lighting line. the second block 38 controls the voltage of the light line section, the block 39 controls the current of the light line section, sensor 40 controls the voltage pulses of the light line section, sensor 41 controls the current pulses of the light line section. In parallel with the coil 10 of the lighting contactor 11, the relay 42 of the control is connected. Executive point 12 also contains an encoder 43, the first input of which is connected to the first switching contact 44 of the control relay 42, the disconnecting group of which is connected to the output of the power supply voltage control unit 36, and closing to the output of the first light control unit voltage line 37. The second input of the encoder 43 is connected to the first switch of the contact 45 of the lighting on contactor 11, the disconnecting group of which is connected to the output of the second control unit 3 for controlling the voltage of the light line section, and the closing group is connected to the output of the light source current control unit 39. The output of the encoder 43 is connected to the first input of the switch 30.2 by a two-wire | Noah line, one of whose wires is connected to pin 46, connected to the neutral wire of the supply network. The second input of the switch 30.2 is connected to the second switching contact 47 of the lighting on contactor 11, the disconnecting group is connected to the output of the sensor 40 controlling the voltage pulses jniacTKa of the lighting | line, and the closing group to the lighting sensor 41 of the current line pulses. The control input of the switch 30.2 is connected to the first and second inputs of the encoder 43. The output of the switch 30.2 is connected {connected to the input of the analyzer 48 sign JKOB. The output of the analyzer is 48 characters connected with the control input of the alternating current key 49 connected between the connection point of the coil 10 of the lighting-switching contact 11 with the control front wire 9 and the switching contact 50 of the control relay 42, the disconnection rpynrta of which is connected to the output 51 for connection to the phase conductor of the power supply network 13, and the closure of the group with the left power supply wire of the coil 10, 568 connected to the output 45 connected to the neutral conductor of the power supply network 13. I At point 1 of the control, the current relay 52 is turned on in communication line 2. The output of current relay 52 is connected to the input of the relay trigger 53. The first output of the relay trigger through time pulse converter 54 is connected to pulse counter 55, the second output of relay trigger 53 through time pulse converter 56 i is connected to pulse counter 57 In addition, to link 2 At point 1 of the control, the telecontrol transmitter 58 is connected, and at executive point 3, the telecontrol receiver 59 is connected to the communication line. At the execution point 3, the poles ABC of the supply network 6 are connected to the lighting contactor 5 via fuses 60-62. The current line portion control unit 23 is connected to the lighting line section 7 through current transformers 63-65, and the current pulse sensor 25 of the lighting line section is connected to the phase conductor of the lighting line section 7 connected to output 8 via a current transformer 66. The secondary windings of the current transformers 63-66 are connected by a common wire with a connection lead to the neutral wire 31. At the operating point 12 of the ABC pole of the supply network 13 are connected to the lighting contactor 11 via lighting fuses 67-69. The current control portion 39 of the illumination line portion is connected to the illumination line portion 14 via current transformers 70-72. A sensor 4t for monitoring current pulses of the illumination line portion is connected to the phase conductor of the illumination line portion 14, which is connected to terminal 15 via a current transformer 73. The secondary windings of current transformers 70-73 are connected by a common wire with a connection lead to zero wire 46. Electrical circuits of power supply voltage control units 20 and 36, as well as the first voltage control units 21 and 37 of the lighting line sections are identical (Fig. 2) and contain a three-phase driver 74, the half of which is the input of this unit and are connected to three-phase controlled lines. A thyristor 75 is connected to the output of the three-phase rectifier 74. Parallel to the thyristor 75 there is a chain from resistor 76 and a capacitor 77, the point of the compound which dinistorov through 78 is connected to the control. thyristor electrode 75. The cathode of the thyristor 75 is connected to the first terminal of the resistor 79, the second output of which is the output of the voltage control unit. The electrical circuits of the second blocks 22 and 38 of the voltage control of the illumination line section are identical (Fig. 3). The circuit of the second voltage control unit 22 comprises a three-phase expander 80, the poles of which are the input of the second voltage control unit. A resistor 81 is connected to the output of the rectifier 80, the second output of which is the output of the second voltage control unit. . The electric circuits of blocks 23 and 39 of the control of current of the sections of the illuminating line are identical. The current control portion 23 of the light path portion (Fig. 3) contains a current relay 82-84 connected to the secondary windings of the current transformers 63-65. The opening groups of contacts 85 of the relay 82-84 are connected in parallel and connected between the positive field of the power source and the resistor, the second output of which is the output of the current line section control unit. The negative pole of the power source is connected to the connection point of the relay 83 with the secondary current transformer. The sensors 24 and 40 pulses of the direction of the light line section have the same electrical circuits. The sensor 24 of the voltage pulses of the lumen of the illumination line (Fig. 3) contains a relay 89 connected to the phase and zero wires of the illumination line section. Parallel. The relay 89 through the disconnecting contact 90 of this relay is connected to a voltage divider 91 whose average output is the output of a voltage pulse sensor on a part of the illumination line. The sensor circuits 25 and 41 pulses of the current of the line section of the illumination are identical. The sensor 25 for current pulses of the illumination line section (Fig. 3) contains a trans-reactor 92, the secondary winding of which is connected to a voltage divider 93, the middle output of which is the output of a sensor of current pulses of the lighting line whose input is the primary winding of the trans-reactor 92. The secondary winding of the trans-reactor and its primary winding is connected by a common wire. The electrical circuits of the encoders 27 and 43 are single. The electrical circuit of the encoder 27 (FIG. 4) contains a relay 94. connected to the first input and a relay 95 connected to the second input via the closing contact 96 of the relay 94. The positive pole of the encoder's power supply is connected to the positive power bus via a switching contact 97 relay 94. The closing group of contact 97 is connected to the power bus through the closure contacts 98 of the relay 95, and the breaking group of contact 97 is connected to the positive power bus of the encoder. Between the positive and negative busbars of the encoder are included a pulse generator containing a single junction transistor 99, the base circuits of which are connected through a resistor 100 and a transformer 101 to a stabilizer of Zener diode 102 and a resistor 103, and a pulse counter containing thyristors 104106, the coils of which are connected to the anode circuit relay 107-109. A capacitor 110 is connected between the anodes of thyristors 104 and 105, and a capacitor 111 is connected between the anodes of thyristors 105 and 106. The control junctions of thyristors 104-106 through the switching contacts 112 of the relay 107 and 113 of the relay 108 are connected to the secondary winding of the transformer 101. The emitter circuit of the single junction transistor 99 connected to a capacitor 114, a bridged closing CIRCW pin 115 of the relay 94 and a disconnecting contact 116 of the relay 95, as well as the closing group of the switching contact 11 7, the disconnecting group of which is connected between the capacitor 114 and switching to with a touch 118 of the relay 107. The opening group of the switching contact 117 is connected to the positive power bus through a resistor 119, and the disconnecting group is connected to the connection point of the closing contact 120 of the relay 95 connected to the positive bus powered through a resistor J21 and the disconnect contact 122 of the relay 94 connected with a positive power supply bus through a resistor 123. The first power supply terminals of capacitors 124 and 123 are connected to the positive power supply bus, the second output of capacitor 124 is connected to the switching contact 126 of relay 107, the disconnecting group and 127 which through a resistor T28 is connected to the negative power bus, and the closing group is connected to the cathode of diode 129. The second lead of the capacitor 125 is connected to the switching contact 130 of the relay 108, the breaker group of which is connected through the resistor 131 to the negative power bus, and the closing is connected to the cathode of the diode 132. The anodes of the diodes 129 and 132 are interconnected. The connection point of the anodes of the diodes 129 and 132 is connected to the disconnect switch terminal 133 of relay 94 with the first output wire of the encoder connected to the zero terminal 31 and the closing contact 134 of relay 95 with the second output wire of the encoder. The positive power bus is connected by the opening contact 135 of the relay 94 to the second output wire of the encoder and the closing contact 136 of the relay 95 to the first output wire of the encoder. The electric circuits of the switches 30.1 and 30.2 are identical. The switches 30.1 and 30.2 (Fig. 5) contain a relay 137 connected to the first control input. A relay 139 is connected to the second control input through the closing contact 138 of the relay 137. The contact of the switching contact 140 of the relay 139 is connected between the first input of the switch and the opening of the switching contact of 141 of the relay 139. Loop of the switch 140 of the contact 140 is connected to the second input of the switch, and the closure center -r5T1pa of the switching contact 141 of the relay 139 is connected to the first input of the switch. The switching contact 141 operates with a time delay for switching with respect to the moment of supplying voltage to the relay 139. The opening group of the switching contact 142 of the relay 137 is connected between the second input of the switch and the closing group of the switching contact 143 of the relay 137, and the closing group of the switching contact 142 connected between the switching contact 141 of the relay 139 and the closing group of the switching contact 143 of the relay 137. The switching contact 143 operates with a switching time delay relative to the moment of removal voltage from the relay coil 137. Electrical circuit analyzers 33 and 48 are identical characters. The analyzer 33 characters (Fig. 6) contains thyristor optocouplers 144 and 145, the LEDs of which, connected in anti-parallel, are connected to the input of the analyzer signs. The photothyristors of optocouplers 144 and 145 are connected through resistors 146 and 147 to the anodes of thyristors 148 and 149, and the anode of thyristor 149 is connected through resistor 147 and phototiristor of optocoupler 144 to the control electrode of thyristor 148, and connected to anode of thyristor 148 through resistor 146 and phototiristor of optocoupler 148 the thyristor control transition 149. The first output wire is connected to the thyristor 148 anode, the second output wire is connected to the thyristor 149 anode, and the positive power bus is the third output cable of the analyzer 33 characters. At the executive point 3, the output wires of the analyzer are 33 characters. At the executive point, 3 output wires, and an analyzer of 33 characters is connected to the input of the delay element 34, the relay coil 150 is connected to the first output wire, the relay coil 151 is connected to the second output wire, and the common coil points of the relay 150 and 151 are connected to the third output wire analyzer 33 characters through a series-connected disconnecting contacts 152 and 153, respectively, relays 150 and 151. Contacts 152 and 153 have a time delay PT and T for opening relative to the moment the relay operates. The output of the delay element 34 are two series-connected break contacts 154 and 155 of relays 150 and 151 (Fig. 7). In time T for opening contact 152 is less than the time delay T1 for opening contact 153. At executive point 12, the analyzer output of 48 characters is connected to

13.1

control input key 49 AC. The key 49 of the alternating current (FIG. 8) is made in the form of a power circuit from a triac 156 and a resistor 157 connected between the phase control wire of the coil 10 of the contactor and the switching contact 50. The AC key contains a transformer 158, the primary winding 159 of which is connected in parallel to the power circuit from of the triac 156 and the resistor 157. The secondary winding of the transformer 158 is divided into two sections 160 and 161. The connection point of the sections 160 and 161 is connected through the thyristors 162 and 163 to the cathode of the triac 156 through the resistor 164 Inonii to pervm poles zamykakndih contacts 1,65 and 167 respectively 166 and relay 168. The second contact terminal 165 connected to an end section t60 of the transformer secondary winding 158 and the second contact terminal 167 - the end section 161 of the transformer. The thyristor control transition 163 is connected to the phase shifter 169. I

Thyristor control transition 162

through a chain of resistor 170 and relay coil 171 is connected to capacitor 172 plates. Negative capacitor plate 172 is connected to the junction point of sections 160 and 161 of transformer 158, and the positive plate of this capacitor is connected via diode 173 to the junction point of the first poles of the contact terminal 174 of relay 166 and the closing contact 175 of the relay 168 The second poles of the contacts 174 and 175 are connected respectively to the sections 161 and 160 of the transformer 158. The catupps of the relay 166 and the relay 168 through the rammer contact, 176 of the relay 171 are connected to the control input dy AC switch 49, and relay coil 166 is connected to the first output conductor, the relay coil 168 to a second pryuvodu vEsoda and the contact 176 is connected to the third wire output analyzer 48 characters. In parallel with the resistor 157, a rectifying bridge t78 is connected through resistor 177, the output of which is connected to the LED of the optocoupler 179, whose photo thyristor is connected between the connection point of the resistor 170 s

14

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relay coil 171 and thyristor cathode 162.I

Control point 1 (FIG. 9) contains a current relay 52, the coil 180 of which is turned on in line 2 of the communication, and the switching contact 181 is connected to the control circuit of the relay trigger 53. Relays are connected to the power buses of the relay trigger 53

182 through the thyristor 183, relay 184 through the thyristor 185, relay 186 through the thyristor 187. Between the anodes of the thyristors 183 and 185, a capacitor 188 is connected. Positive power pole of the relay trigger through the disconnecting contact 189 of the relay 186 and the resistor 190 is connected to the switch1 of contact 181 of the current relay 52 , the breaker group of which is connected via the closing contact 191 of the relay

184 to the control electrode of the thyristor 183, and the closing group to the switching contact 192 of the relay 182. The opening group of contacts 192 is connected to the control electrode of the thyristor 185, and the closure of the group to the control electrode of the thyristor 187. The connection point of the resistor 190 and contact 189 is connected the switching contact 193 of the relay 182, the closing group of which is connected to the second output of the relay trigger 53 connected to the time by a pulse converter

56, the opening group of the switching contact 193 is connected via the closing contact 194 of the relay 184 to the first output of the relay trigger. The time of the pulse converter 54 is connected to the first output of the relay trigger 53.

A positive power bus relay relay 53 is connected to the positive pole of the source

power through the disconnecting contact 195 of the Reset button, through the disconnecting contact 196 with the retarder acting when the relay 197 is triggered and returned, and the disconnecting contact 198

relay 197. The relay coil 197 is connected at one end to the junction point of contacts 198 and 196, and the other end to inputs 199.1 and 199; 2 relay flip-flops 53. Parallel to the relay coil 186 a signal lamp 200 is connected Fault in the cascade and parallel to the relay coil 197 signal lamp 201 Reset connected. The output of the relay trigger 53 is connected to a pulse converter 54 containing a single junction transistor 202, the emitter of which is connected to the output circuit of resistor 203 and capacitor 204. The first base of transistor 20 is connected to the positive pole of the power through a resistor 205, and the second base is connected to the primary winding pulse transformer 206, the secondary winding of which is connected to the input of counter 55 of pulses, the counter cells of which are made in the form of thyristors 207-210, to the anodes of which are respectively connected bmotki relays 211-214, a parallel but which includes indicator lights 215-217. Between the thyristor anodes 207 and 208, capacitor 218 is on, between thyristor anodes 208 and 209, capacitor 219. The control electrode of thyristors 207 and 2 is connected to the switching contact 220 of the 2P relay. The control electrode of the thyristor 209 is connected ;, to the closing group of the switching contact 221 relay 208, the disconnecting group of which is connected to the switching contact 220. The control elec- trode of the thyristor 210 is connected to the closing group of the switching contact 222 of the relay 209, the disconnecting group 1 pa of which is connected to the switching contact 221. contact 222 is connected to the secondary winding of the pulse transformer 206, Interrupts contact 223 relay 214 is connected between the negative power bus of the pulse counter and the wire connected to the second end of the relay coil 197 in the relay trigger 53. The time pulse device 56 is similar to the time pulse design device 54. The scheme of the counter of 5 pulses is similar to the scheme of the account, the pulse of 55 pulses. The control and monitoring system for three-phase outdoor lighting networks works as follows. In the disconnected state of the cascade, the positive-polarized current flows through line 2 of the connection + 3de while the contact 181 of the current relay 52 switches the circuit from the resistor 190 and contact 191. Since the contact 191 is open, the control signal of the thyristor 183 does not and the relay trigger 53 is not working. With a positive polarity of the current in the link 2, the remote control receiver 59 does not apply voltage to the coil 4 and the contactor, 5 switching on the illumination of the executive point 3 is open. The absence of voltage in the line section of the illumination ensures that the lighting contactor 11 of the control point 12 is not switched on, since the coil 10 is also not energized. Since the coil of the relay 26 of the control unit 3 is de-energized, the switching contact 28 connects the output of the supply voltage control unit 20 to the ABC poles of the power supply 6. With the integrity of the fuses 60-62, the three-phase rectified voltage is removed from the rectifier 74 units 20, through an open thyristor 75, a resistor 79 is fed to the input of the encoder 27 of the execution point 3. The supply of voltage to the inputs of the encoder 27 provides in the encoder circuit the switching on of the relay 94. when turned on, P 96 connects the coil 27 to the input of the encoder 27 relay 95 and also opens contact 122, 135 and 133 and closes contacts 115, switches contacts 97. The signal removed from the input of the encoder 27 is simultaneously sent to the control input of the switch 30. t, in which the relay 137 operates, is connected by contacts 143 and 142 This relay is the first input of the switch to its output. Since the control relay 42 is de-energized, similar switching is performed at the executive station 12 in the power supply control unit 36 of the encoder 43 and the switch 30.2. . The disconnected state of the outdoor lighting cascade is controlled by two emergency situations: the disappearance of voltage from the mains side due to faulty fuses that may burn during the cascade operation or removed by service personnel, and contact with the external voltage lighting line as a result of touching the wires general purpose networks or welding of lighting contact insulators.

When an emergency situation arises, for example, a third-party voltage is applied to the section 14 of the lighting line, this voltage is fed to the input of the second voltage control unit 38 of the section of the lighting line of the actuating station 12.

In the second block 38 of monitoring the voltage of a portion of the illumination line, the voltage through the rectifier 80 and the resistor 81 goes to the output of this block and then through the switching contact 45 is fed to the second input of the encoder 43 and the control input of the switch 30.2. In encoder 43, relay 95 is turned on, and in switch 30.2, relay 139 is turned on. When relay 95 is turned on in encoder 43, contact 116 opens and contacts 98, 120, 134, and 136 close. Depressor of capacitor 114 by contact 116 and connect the encoder circuit to contact 98 to power supply It provides processing of the first time delay T, determined by the value of the resistor 119 and the capacitance of the capacitor 114. Time delay Tj is necessary for the detuning from single and short operations of the control blocks of the light line sections during switching.

When the capacitor 114 is charged to the voltage of the single junction transistor 99, the transistor opens, providing a discharge of the capacitor 114 to the primary winding of the transformer 101, i.e. the formation of a single pulse. At the first single pulse after testing the time T, the thyristor 104 is triggered, turning on the relay 107 which switches the contact 118, connects a resistor 121 to the capacitor 114, switches the contact 112 connected to the secondary winding of the transformer 101 and controls the switching 126, providing Connecting a capacitor 124, charged through a resistor 128 from the power rails, to the output of the encoder through the contacts 134 and 136. The magnitude of the resistor 121 ensures that the delay time Tj is tested (Fig. Ia).

After a short time, Then from the secondary winding of the transformer 101

A second pulse is removed that unlocks the thyristor 105. Turning on thyristor 105 provides for locking thyristor 104, turning off relay 107 and turning on relay 108. Relay 108 switches contact 113, connected to the secondary winding of transformer 101, controls thyristor 106, and also switches contact 130, which provides connecting the capacitor 125 charged through the resistor 131 from the power rails to the output of the encoder via the contacts 134 and 136. Disabling the relay 107 leads to connecting the charge circuit of the capacitor 114 through the resistor 119, which ensures that Yemeni T.

After testing the time T, a third pulse is removed from the transformer 101, which unlocks the thyristor 106, when the relay 109 is turned on, and the thyristor 105 is turned off, which disconnects the relay 108. Relay 107 switches pin 117, disconnecting the capacitor 114 from the charging circuit and shunting it.

Thus, when a third-party voltage from the output of the encoder 43 arrives at the second input of the switch 30.2, two pulses of negative polarity are applied to the neutral wire of the network with a time interval Td between them. These pulses pass through the contacts 140 and 141 of the switched on relay 139 and the contacts 142 and 143 of the also turned on relay 137 and through the output wires of the switch 30.2 are fed to the analyzer input of 48 characters. In the analyzer, 48 characters of each single voltage pulse of negative polarity affects the LED of the optocoupler 145, which includes the thyristor control circuit 149. Unlocking the thyristor 149 provides a voltage supply to the first 48-character analyzer output wire. This voltage ensures that relay 166 is turned on in AC switch 49. Turning on the relay 166 provides a closure of the contacts 165 and 174 of this relay. In this case, the capacitor 172 is charged by the voltage of the secondary winding section 161 of the transformer 158 through the diode 173, The voltage on the capacitor 172 unlocks the thyristor 162 and when 19 the direct voltage is applied to it from the secondary winding section 160 of the transformer 158 to the control transition simis To torus 156 a control current is applied. The unlocking of the triac 156 is determined by the parameters of the phase shifter 169, which unlocks the thyristor 163, and is equal to 90. When the triac 156 is unlocked from pin 51 through the resistor 157, current flows to the coil 10 phase control wire, the current flowing through the resistor 170 is fixed by an optocoupler 179, whose photo thyristor shunts the control junction of the thyristor 162 and increases the current in the winding of the relay t71 to the magnitude of the operation current. The operation of relay 171 leads to opening of the contacts 176, which interrupt the power supply circuit of the coil of the relay 166..Relay 166 turns off, opening contacts 165 and 174. When the second pulse arrives, through the time T to the input of the analyzer 48 characters, its operation and operation of the AC key 49 repeat in the same order. Thus, upon occurrence; of the emergency situation on the light section 14; by the control wires 9 from the executing station 12 and by the wires of the light line section 7 two information pulses of negative polarity and and j are transmitted with a temporary pause TD between them (FIG. 10 ). The polarity of the pulses is encoded by the I symptom of a malfunction, and the time period for the pause T is the number of the operating point where no fault was found: good condition. In the executive point 3, the information voltage pulses are detected by the voltage pulse sensor 24 of a part of the broadcast line, and from the voltage separator 91 voltage sensor 24 pulses through the switching contact 32 are fed to the first input of the switch 30.1. In switch 30, an information pulse passes through pins 140-143 and 33 characters are input to the analyzer. Since the AC key 49 at the executive point 12 generated voltage to polarity polarity, and the sensor 24 voltage pulses and commutator 30.1 did not change the polarity of the signals, in the analyzer 33 signs 6 are used 6 optocoupler 145, which commutes the circuit thyristor control 149 The unscrewing of the thyristor 149 ensures the presence of a 33-character voltage in the first output wire of the analyzer, which turns on the relay 150 in delay element 34. Turning on relay 150 opens the contacts 154, i.e. decoupling the resistor 35 for a time-pause T, which is determined by the time setting of the contact 152. Opening the contact 152 through the time Tj after the operation of the relay 150 interrupts the power supply circuit of the relay 150. Since the power supply circuit of the relay 150 of the delay element is interrupted, the analyzer thyristor 149 33 characters locked up. Thus, by acting on the analyzer 33 characters of a single pulse of negative polarity in the delay element 34, the resistor 35 is bypassed to a time delay T, followed by restoring the analyzer 33 characters and the delay element 34 to its original position. A series of two single negative pulses provides a sequential deshung of a resistor 35 for the time Ta with a time pause T4 between the de-shunting (Fig. 10 a). When the resistor 35 first shunts by the time Ta on the link 32, the current decreases to a value T, which causes the current relay 52 to trip. When current relay 52 is disconnected through resistor 190, contacts 181 and 192 apply positive voltage to thyristor control electrode 185, which unlocks thyristor 185. Unlocking thyristor 185 ensures switching on relay 184, which connects time pulse converter 54 to contact power buses of relay trigger The time pulse converter 54 converts the pause time Ta into the number of pulses P (. Each pulse time of the pulse converter 54 is recorded in the pulse counter 55 by unlocking one of the thyristors 207-210, which in turn ensures the activation of one of the relays 211-214. The first pulse triggers the relay 211 and the light 215 come on, the second pulse turns on re-, le 212, and the relay 211 turns off, the light 216 lights, and the light 211 goes out. The warning lights 215 and 216 in the counter 55 will be a digital indication of a fault sign, Similar signal lights in the pulse counter 57 designate the number of the control point from which the transmission is transmitted. After the end of the time pause T, the resistor 35 is bridged and the nominal current is restored in the communication line 2, enabling the relay 5 to turn on. in this case, the positive power line of the relay trigger is connected to the control electrode of the thyristor 183 through the closed contact 191 of the relay 184 providing unlocking of the thyristor 183, locking the thyristor 182 and turning off Relay 18.4. When the relay 182 is turned on, the contact 193 is turned on, the power supply circuit is opened, the time of the pulse converter 54 and the supply voltage is applied for the time of the pulse converter 56. The time of the pulse converter begins to generate clock pulses, counting the time delay T4, the counter 57 reads out the pulses P2 coming from time. pulse generator 56. With the secondary decrease of the current in the communication link 2, the current relay 52 switches off again and its contacts 181 switch over the switching contact 192 of the control electrode of the thyristor 187 with Flax bus power relay trigger. The thyristor 187 is unlocked, turning on the relay 186, which, by opening the contacts 189, interrupts the supply voltage for the time of the pulse converter 54, providing the counting end of the pulses by the counter 57 when time T is on. When the relay 186 is turned on, the voltage of the signal lamp 200 is applied to the board Malfunction cascade. The subsequent, through time T, restoration of the nominal current value ensures switching of contact 181, switching the positive supply bus circuit to contact 191, but since this contact is open, after the second information pulse is fixed in the relay trigger, no changes take place. The dispatcher reads the information D), and 2 from counters 55 and 57 and opening the contact 622 and 195 of the Reset button returns the relay trigger 53 to its initial state. The technology of information transmission by voltage pulses of positive polarity is shown in Fig. Yu. In case of faulty fuses x 67-69 (at the executive point 12, the fuse can burn out during the outdoor lighting cascade operation) the thyristor 75 of the supply voltage control unit 36 is locked, while from its output to the first input of the encoder 43 and to the control input of the switch 30.2 voltage does not flow. The relay 94 of the encoder 43 and the relay 137 of the switch 30.2 are disabled. Disabling relay 94 in the encoder 43 causes the power supply to be connected by contacts 97 to the encoder's positive power bus, as well as closing contacts 122, 135 and 133 and opening contact 115, the technology of the encoder 43 is similar to Bbmie described under the condition that the introduction of a resistor 123 by contacts 122 provides testing of the time delay T between two positive pulses relative to the time delay T. The AC key 49 generates two positive pulses (J | and Ug, which by means of the execution point 3 broadcast Cozy point 1 of the control. In this case, the positive voltage pulse is encoded by a temporary pause Tj, and the time of the melio pauses of the current in the line. The connection is determined by the delay TJ, The time T is decrypted by the counter 55 into the digital information P, and the delay T is decrypted by the counter 57 in information P2 (fig.Y.), In this case, the difference and TlmezhT should be delayed by time delay T and not be summed up with a time delay T, t, e, | - «- tT, - Tp For example, if the time delay T is 2 s, and the time delay T is 3 seconds, the time pause T, between the voltage pulses Negative. polarity and a temporary pause T between the pulses of the positive polarity should be less than 1 s. The signal for switching on the outdoor lighting cascade from the transmitter of the telecontrol 58 is made by changing the polarity of the current in the communication line 2 to a negative (-3dd). In this case, a voltage is applied to the coil 4 of the execution point 3 from the remote control receiver. The passage of current through the coil 4 of the contactor ensures the closure of the contacts of the contactor 5 to turn on the lighting and to supply voltage to the lighting line section 7, as well as to apply voltage through the control wires 9 to the coil 10 of the contactor 11 to turn on the lighting 11 of the actuator 12, which supplies voltage Pokenie to the section 14 of the lighting line 14, controlling by means of the wires 16 controlling the section 19 of the lighting line connected to the executing point 17. At the same time as the contactors 5 and 11 are turned on, the executive control relay 26 turns on The unit 3 and the relay 42 of the control unit 12. At the Intellect point 3, the switching contact 32 connects the sensor output 25 of the current of the lighting line to the first input of the switch 30.1. The switching contact 29 connects the output of the lighting control section of the current of the lighting line to the second input of the encoder 27 and the switching contact 28 connects the output of the first block 21 of the control of the voltage of the light line section to the first input of the encoder 27. At the executive point 12, the switching contact 47 connects the sensor output / 41 of the control The current pulses of the lighting line section to the first input of the switch 30.2, the switching contact 45 connects the output of the current line monitoring section 39 to the second input of the encoder 43, and the switching contact 44 connects the output of the first lighting voltage section 36 of the encoder to the first input of the encoder 43 The switching contact 50 of the control relay 42 disconnects the AC switch from the output 51 connected to the phase conductor of the supply network 13, and connects the AC switch to the control wires 9 parallel to the catuips 10 contact ra inclusion osve-55

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With the switchings made in the first blocks 21 and 37 of the controller of the analyzer 48 characters, which includes the relay 168 in the key 49 trans. belt current. The switching on of the relay 168 of the voltage section of the illumination line of thyristors 75 is unblocked, since constant voltage is removed from rectifier 74, and this ensures the switching on of relay 94 in encoders 27 and 43 and the switching on of relay 137 in switches 30.1 and 30.2.When the cascade is on outdoor lighting is monitored for the presence of voltage in the light path sections. The magnitude of the current load, depending on the number of healthy light sources, is controlled by turning on the relay 82-84, which provides the opening of the contacts 85-87 of the relay data. When an emergency occurs in the outdoor lighting cascade, for example, when the fuse 67 in the execution unit 12 burns, the thyristor 75 of the first block 37 controls the voltage of the lighting line section and is locked to the first input of the encoder 43, as well as to the control input of the switch 30.2, the supply voltage stops . In this case, relays 94 in the encoder 43 and relays 137 in the switch 30.2./ disconnect. Switching off the relay 94 in the encoder 43 closes the contacts 122, 133 and 135 and connects the positive pole of the power supply terminal 97 to the positive encoder bus. In this case, the encoder 43 according to the described technology generates two single pulses, the polarity of which is determined by the passage of pulses through the contacts 133 and 135 and is positive with respect to the neutral wire of the supply network. The duration of the time interval between the pulses T is determined by the size of the resistor 123. In the switch 30.2, the output of the encoder 43 is connected to the input of the analyzer 48 characters by switching contact 142 connecting the second input of the switch 30.2 to the output of the switch. I Positive pulses generated by the encoder 43 in the analyzer of 48 characters affect the LED of the optocoupler 144, whose photo thyristor is unlocked and turns on the thyristor 149. Unlocking the thyristor 149 in the analyzer of 48 characters provides voltage to the second wire

ensures the closure of contacts 167 and 175 of this relay, while section 161 of the secondary winding of the transformer is connected to the control transition of the triac 156, and section 160 to the control transition of the thyristor 162. In this case, the alternating key 49 of the alternating current is unlocked in the positive half-period, while the unlocking angle is equal to 90. Since, when the cascade is on, the switching contact 50 of the relay 42 of the control module connects the AC key 49 to the control wires 9 parallel to the contactor coil 10, when the triac 156 is unlocked once In the control gadgets, the current amplitude exceeds the amplitude, the amplitude of the information pulse T in this case is equal to the sum of the amplitudes of the operating current Op and the additive current J.

IH IP IA The current amplitude of the additive is determined by the resistance of the resistor 157

v,

| where U is the amplitude of the network voltage.

Two current pulses and Jg transmitted by wire 9 control (Fig. 10b) are recorded by a current pulse sensor 25 of a portion of the illumination line in which each current pulse by the transreactor 92 is converted into a voltage pulse. The pulses, for example, from the divider 93 of the sensor 25 of the pulpoB current of the light path portion enter through the contacts 32 to the first; the input of the switch 30.1, where it passes through the contacts 140-143, enters the input, the analyzer has 33 characters. Positive pulses ensure the passage of current through the LED of the optocoupler 144 and the switching on of the thyristor 148, whose circuit is connected to the relay 15 of the delay element 34. The inclusion of the relay 151 provides the opening of the contacts 155, i.e. de-shunting the resistor 35 for a temporary pause T, which is determined by the time setting of contact 153. Opening the contact; this 153 interrupts the power supply circuit of the relay 151 and the thyristor 148, as a result of four | Gotiristor 148, is locked, and the delay element 34 and the analyzer 33 characters are set to their original position .

At point 1 of the control according to technology, two pauses and a decrease in the current in the communication line 2 are recorded, simulating pulses of positive polarity, and a pause T between two pulses. The first pause T and pause T are converted into a digital code h and. time by pulse converters 54 and 56 and by counters 55 and 57 pulses by switching relay relay 53, which is controlled by current relay 52.

Thus, the information on the combustion of the fuses is transmitted at the intermediate point 12 (Fig. 10 &),

When the current load decreases in section 14 of the illumination line due to the failure of light sources, for example, in phase wire 13, relay 84 is disconnected, contact 87 and the output of lightning current line section control unit 39 to the second input of encoder 43 and control input of switch 30.2 are closed a voltage is supplied that turns on relay 95 in the encoder 43 and relay 139 in the switch 30.2.

The inclusion of these relays provides the transmission by wire 9 of the control of two current pulses of negative polarity (Fig. 10). When transferring information from the executive point 12 to switch 30.2, contacts 140 of relay 139 or contacts 142, relay 137 disconnects the first input of switch 30.2 and connects the output to the second input of switch 30.2. After the transmission of information in the form of two pulses with a time delay, the larger delay T. + t | , the contacts 141 of the relay 139 or the contacts 143 of the relay 137 are triggered. In this case, the output of the switch 30.2 is connected to its first input to transmit information coming from subsequent execution points.

When the described emergency situations occur in section 19 of the illumination line, informational signals about malfunction fixation in r; the infill section 17 are transmitted via control wires 16 to section 14 of the illumination line and fixed when the cascade is turned on by sensor 41 for monitoring current pulses of the illumination line portion, and disconnected cascade - sensor 40 monitors the voltage pulses of a portion of the lighting line. The voltage pulses from the sensors AO and 41 through the switching contact 47 are fed to the first input of the switch 30.2, their polarity is determined, in the analyzer 48 characters and pulses are received by the AC switch 49 to the execution point 3 ,. where are broadcast to the control point.

In case of emergency situations on the section 7 of the illumination line, the technology of generating information signals at executive point 3 is similar to the technology of generating information signals at executive point 12 (in this situation with direct information transfer to point 1 of control via delay element 34.

For example, when the outdoor lighting cascade was turned off, the contacts of the contactor 5 did not open, due to welding. In this case, the illumination line section 7 will be under voltage in the absence of voltage on the contactor coil 4. At the same time, the second voltage control unit 22 of the section of the illumination line records the voltage in the portion of the illumination line 7, and from its output a voltage is supplied through the switching contact 29 to the second input of the encoder 27. In the encoder 27, the relay 166 is triggered and, using the technology of the encoder 43, when the relay 166 is triggered from the output of the encoder 27 via the switch 30, the analyzer 33 drives two negative polarity pulses to the delay element 34. The delay element 34 doubles the decoupling of the resistor 35 by the time T with the belt pause T with meldu them. At point 1 of the control T, it is decrypted by the counter 55 into the digital information h. indicating the symptom of malfunction, and the temporary pause T5 is decrypted by counter 57 into digital information 1 indicating the number of the operating point. .

When fixing a single pulse. in sections of the illumination line or a series of pulses whose time code does not correspond to the information signal, the relay trigger for a long time relays 184 or 186 in the relay trigger. At the same time, a series of pulses is triggered to the 55 or 57 pulses of the thyristor 210, which activates the relay 214. Relay 214, its contact 233 turns on the power supply circuit for relay 197 of the relay trigger 53. Relay 197 opens contact 198, disconnecting the positive bus of the relay power trigger from the power supply. In this case, the de-energized relays 182 and 184 and also the counters 55 and 5 7 of the pulses take the initial position, the signal lamp 201 Reset lights up and, after a time delay of 0.5 seconds, the relay 197 is disconnected by opening the contacts 196, after 1 s the contacts 196 are closed and the relay trigger is ready for work. When the link 2 is broken, the switching contact 181 continuously switches the resistor 190 circuit to the switching contact 192, ensuring that the relay 184 operates for a long time. In this case, the counter 55 periodically switches on the relay 214, which automatically clears the information according to the described technology.

. Thus, information about arbitrary pulses recorded by the control system at the execution points is automatically reset with a short ignition of the lamp 201. When the link 2 of the link is broken, the dump 201 periodically lights and goes out.

The three-phase outdoor lighting control and monitoring system with cascade switching reduces the time needed to determine the failure of the outdoor lighting network, namely, it allows to accurately determine the section of the lighting line in the cascade where the failure has occurred. The list of detected faults includes: determining the presence of voltage in the light line sections, monitoring the rated current, hitting the external voltage on the light line section, monitoring the communication line. The proposed cascade control method allows unlimited expansion of the spectrum of transmitted information signals by changing the information transmission technology.

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Claims (1)

CONTROL AND MONITORING SYSTEM FOR THREE-PHASE EXTERNAL LIGHTING NETWORKS WITH CASCADE ON, containing the executive points of each section of the lighting line, the coil of the lighting contactor, the first of which is connected by a communication line to the control point, and each of the coils of the lighting contactors of the executive points of subsequent sections of the lighting line is connected control wires with leads for connecting to the phase and j neutral wires of the previous section of the lighting line, each of them. astrov line | lighting has an output for connecting to the neutral wire of the supply network, which in each of the execution points, except the first, is connected to the output for connecting to the neutral wire of the network of the previous section of the lighting line, characterized in that, in order to reduce the time to determine the malfunction in the outdoor lighting network, the executive points of each section of the lighting line are equipped with a power supply voltage control unit, the first and second voltage control units of the lighting line section, a current control unit a lighting line section, a voltage line voltage pulse sensor, a lighting line section sensor, an encoder, a sign analyzer, a switch, a monitoring relay, the coil of which is connected in parallel with the lighting enable contactor coil, and the sign analyzer _’s input is connected to the switch's JS output, the first input the switch is connected to the first switching contact of the lighting enable contactor, the closing group of which is connected to the output of the current pulse sensor of the lighting line section, and disconnecting - to the output of the voltage sensor of the section of the lighting line, the second input of the switch is connected to the encoder output by a two-wire line, one of the wires of which is connected to the output for connecting to the neutral wire of the supply network, the first input of the encoder is connected to the first switching contact of the monitoring relay, the disconnecting group of which is connected to the output of the voltage control unit of the supply network, and the closing to the output of the first voltage control unit of the lighting line section, the second input of the encoder is connected to the second contact contact 992961Г ^ha Т) 5 connection, the closing group of which is connected to the output of the current monitoring unit of the lighting line section, and the disconnecting group - to the output of the second voltage monitoring section of the lighting line section, the first and second inputs of the encoder are connected to the first and second control inputs of the switch, the control point is equipped with a current relay included in the communication line, a relay trigger, two time-pulse converters and two pulse counters, the input of each of which, through the corresponding time-pulse converter, is connected to the first and second the output points of the relay trigger, the executive point of the first section of the lighting line is additionally equipped with a resistor 'included in the communication line, a delay element, the output of which is connected in parallel with the specified resistor, and the input is connected to the sign analyzer, each executor is the point of the sections of the lighting line, except the first, it is additionally equipped with a terminal for connecting to the phase wire of the supply network and alternating current switches connected between the phase control wire and the second switching contact of the monitoring relay, which closes the groups the disconnecting group is connected to the control neutral wire with an output for connecting to the phase wire of the supply network, while the control input of the AC key is connected to the output of the sign analyzer of the executive point of the corresponding section of the lighting line.