RU2037937C1 - External lighting cascade monitoring method - Google Patents

Abstract

FIELD: electrical engineering. SUBSTANCE: method involves shaping of monitoring pulse at end of last section of cascade with constant repetition rate. Cascade operation is monitored at all ON-stations and monitoring pulses at beginning of cascade section are recorded. Monitoring pulses are shaped at all ON-stations; if fault is detected at ON-station or absence of monitoring pulses is revealed at cascade section, fault detected and number of ON-station are encoded in monitoring pulse. If no fault is detected in ON-station, monitoring pulse translates content of monitoring pulse received at beginning of cascade section. At end of each cascade section, voltage across control wire of second channel is checked and voltage presence across this wire is encoded in monitoring pulse. Data on monitoring pulse voltage is checked for compliance with voltage across control wire of second channel at beginning of cascade section. In case voltages at beginning and end of cascade section do not agree, fault of "OPEN CIRCUIT" type is recorded at control wire of second channel. EFFECT: enlarged monitoring range, in particular, provision for checking second-channel control wire for continuity while it is alive. 2 cl, 3 dwg

Description

 The invention relates to electrical engineering, in particular to methods for remotely indicating the operating modes of an outdoor lighting network, and can be used to control cascading controlled outdoor lighting networks and providing for several lighting modes.

 A known method of monitoring the outdoor lighting cascade, implemented in a standby control system, in which the operation of the night and evening lighting contactors is monitored and, when a malfunction is detected at one of the intermediate switching (power) points, forms a sequence of information pulses at the end of the previous section of the cascade.

The sequence of information pulses is received at the beginning of the cascade section and broadcast along the cascade sections to the executive (first) switching point and then along the communication line to the control room, where control information is analyzed and displayed on the indicator panel [1]
The sequence of information pulses in the described system has the structure of two series of pulses separated by a pause, and the number of pulses in one series determines the address (number) of the switching point that detected the malfunction, the number of pulses in another series is the malfunction code. Thus, the sequence of information pulses is a control premise with two information fields: the location and type of malfunction.

 A disadvantage of the known method of monitoring the cascade of outdoor lighting is that it is insensitive to an accident such as a break in the control phase wire, which is used to transmit control information.

A known method of monitoring the cascade of outdoor lighting, in which the presence of voltage at the end of each section of the cascade is monitored, information pulses are recorded at the beginning of each section and, if there is voltage at the end of the last section of the cascade, a sequence of information pulses of a given structure is formed in it; in the presence of voltage at the end of each section of the cascade, except the last, and fixing the presence at the beginning of the next section of the cascade, sequences of information pulses form at the end of this section a sequence of information pulses of the same structure, and if there are no indicated pulses at the beginning of the next section of the cascade, form at the end of this section the sequence of information impulses of the structure corresponding to a given section of the cascade, moreover, the health of the cascade is judged by the structure of telnosti data pulses, written to the beginning of the first stage portion [2]
In the specified known method of monitoring the cascade of outdoor lighting, the passage of information pulses through individual sections of the cascade is controlled, i.e. serviceability of communication equipment and integrity of the wire phase information transfer.

 As a parameter of the structure of the sequence of information pulses identifying a specific section of the cascade, the frequency of information pulses is used. In this case, the frequency of information pulses of various sections of the cascade decreases as the section approaches the first section of the cascade. This allows us to determine the address of the switching point in the cascade closest to the first section of the cascade from the adopted frequency of information pulses, which did not record information pulses at the beginning of the subsequent section of the cascade.

 If the cascade uses two lighting modes, for example night and evening, then at each switching point there are two contactors, the receiving coils of which are connected to the wires of two phases, and control of both control channels is desirable.

 The disadvantage of this method of monitoring information is that it controls the integrity of only the wire used to transmit control information. To control the integrity of the wires of two control channels (night and evening), it is necessary to build two separate control channels on wires of different phases.

 The objective of the invention is to obtain the possibility of expanding the field of control, in particular, the coverage of the control integrity of the control wire of the second channel in the presence of voltage on it.

 This is achieved by the fact that in the method of monitoring the outdoor lighting cascade, namely, at the end of the last section of the cascade on the wire selected for one control channel, control messages are formed with a constant repetition period, the operation of the cascade is monitored at all switching points and control messages are fixed at the beginning of the cascade section; at all switching points, except for the executive switching point, form control messages on the control wire at the end of the previous section of the cascade, and on the control switching point on the communication wires with the control room, moreover, if the switching point detects a malfunction or absence of control messages on the cascade section, then the detected fault is encoded in the control package, including the absence of control packages, and the number of the switching point, if the failure is not detected at the switching point, then ontrolnaya broadcast content posting parcels control adopted in early stage portion; at the control room, control packages are received from the executive switching point and the contents of the information fields of the control packages are used to judge the operation of the cascade, at the end of each section of the cascade the voltage on the control wire of the second channel is monitored and the voltage on this wire in the control package is encoded; in each switching point, the correspondence of the voltage information in the control package to the voltage on the control wire of the second channel at the beginning of the cascade section is determined; in the event of a voltage mismatch, a wire break type fault is recorded.

 The technical result of the method of monitoring the cascade of outdoor lighting is achieved due to the fact that when the control wire of the first channel is broken, as in the known method of monitoring the cascade, a malfunction such as a wire break or equipment malfunction is recorded at the switching point. In addition, the method controls the presence of voltage at the beginning and end of the control wire of the second channel, but unlike the known method of controlling the cascade, in the proposed method, information about the presence of voltage at the end of the section is transmitted through the control wire of the first channel to the beginning of the section, where they are compared with voltage at the beginning of the plot.

 The presence of voltage on the control wire of the second channel at the beginning of the section and the absence of voltage at the end of the section can be interpreted as a malfunction such as a wire break. Lack of voltage at the beginning of the wire and the presence of voltage at the end of the wire can mean a complex malfunction, for example, a wire break with the presence of extraneous voltage or a malfunction of the voltage sensors. In the absence of voltage on the control wire of the second channel, a case of an undetected malfunction such as a wire break is possible, but when the voltage on the wire is turned on (trial or on schedule), this malfunction is detected.

 Thus, the proposed method of monitoring information allows you to control the integrity of the wires of the control channels that are not used to transmit control information, if there is voltage on them.

 This result can be used to achieve various secondary technical results. In the simplest case, it is possible to reduce the amount of equipment used for the control information transmission channel by using one control information transmission channel to control the integrity of the wires of two control channels. But it is possible to use this technical result to separate faults such as wire breaks and faults such as hardware failure for one of the control information transmission channels.

 To achieve this result, in the method of monitoring the outdoor lighting cascade, the control information is transmitted through the wires of two control channels, and at the beginning of the cascade section, the situation is analyzed: if there are no information pulses on the wire of only one of the channels, but there is no mismatch in the voltage on the other channel the wire of this channel when the voltage is on, then a malfunction such as a hardware failure is recorded, if there is a mismatch in the voltage, a malfunction such as a wire break, if there is no voltage on the wire, a malfunction such as a wire break or equipment malfunction.

 The coding of information in the control package can be made: the polarity of the information pulse, the presence or absence of the information pulse in the information field, the position or number of information pulses in the information field, or other known methods.

 Figure 1 shows an example of a cascade circuit with two control channels, in which a method for monitoring an outdoor lighting cascade can be implemented; figure 2 an example of the structure and coding of information of the control package used in the method of monitoring the cascade of outdoor lighting; figure 3 is an example of a control circuit, receiving and transmitting control information of the switching point, implementing a method of monitoring a cascade of outdoor lighting.

 The cascade of outdoor lighting (figure 1) consists of three sections. Each of the sections of the cascade contains: terminals 1 of the power source (phases A, B, C and neutral N), receiving coil 2 and contacts 3 of the night light contactor, receiving coil 4 and contacts 5 of the evening light contactor, lighting devices 6 connected to the power wires phases A, B, C and neutral N.

Contacts 3 and 5 of the contactors for night and evening lighting are connected at the beginning of the section of the cascade between the power terminals 1 and the wires of the corresponding phases. The receiving coils 2 and 4 of the contactors of the sections of the cascade, in addition to the first, are connected in parallel to the lighting devices to the control wires (phase 1 wires of phases A and C) of the previous section of the cascade, and the first section of the cascade to the outputs of the actuator 7, for example, the UTU-4M complex. The inputs of the actuator are connected by a telephone pair 8 to the control room
The channel for transmitting control information over sections of the cascade, in addition to the phase A wire for transmitting control information, contains blocks for monitoring and transmitting control information: the final section of the cascade 9 connected at the end of the last section to the wires of the control phases, intermediate switching points 10 connected to the wire for transmitting the control information of the section and the control wires of the previous section of the cascade, the executive switching point 11 connected to the control information transmission wire and the executive device at 7.

 In FIG. Figure 2 shows an example of the structure of the simplest control package containing three functional fields: start (St), second channel control mode (Rv), and address (A). A control package may contain from one to three information pulses. The field St means the beginning of the control premise and always contains an information impulse, the field Pb contains an information impulse if there is voltage on the control wire of the second channel. An information pulse in field A means a detected malfunction, and the number of the tact of finding an information pulse in field A is the number of the switching point that detected the malfunction. The type of fault in this example is not encoded. In cascades of outdoor lighting, information pulses are usually formed due to the "deformation of the wave" of the supply voltage. In FIG. 2 information impulses are presented in conditional form. The transmission cycle is a 50 Hz supply voltage period.

 The control unit and the transmission of control information of the switching point 10 (Fig. 3) contains a clock pulse shaper 12, the input of which is connected to the phase A terminal of the power source, and the outputs are connected to the device synchronization inputs: 13 receiving control messages, information register 14 and forming device 15 a control package connected in series and connected to the wires for transmitting control information (phase A), at the input of device 13 at the beginning of the cascade section and at the output of device 15 towards the end of the previous cascade section; a control device 16, the inputs of which 18 are connected through appropriate sensors to the controlled points of the switch-on point, and the outputs with the inputs of the combinational comparison circuit 19 and the correction circuit 20 of the contents of the register. The outputs of the correction circuits 20 are connected to the parallel input of the register 14, and the combination circuit 19 with one of the inputs of the control circuit. The second input of the combinational circuit 19 is connected to the parallel output of the register 14.

 The devices 13 and 15, respectively, of the reception and transmission of control parcels, as well as the control device 16 of the control unit can be implemented in the same way as in the known methods of monitoring the cascade of outdoor lighting.

 The control information transmission and control information blocks 11 and 10 coincide in the functional diagram and may differ in the circuit diagram of the control premise generating device 15, since the control information is transmitted at the switching on point taking into account the functioning of the executive device 7.

 The control information transfer and control units 9 and 10 are characterized in that the first has a simplified control device 16 (only the voltage on the control wire of the second channel is monitored), does not have a control information receiving device 13, correction circuit 20, or combination circuit 19.

 The control of the cascade of outdoor lighting is implemented as follows.

 The generator 12 clock pulses of blocks 9, 10, 11 of the control and transmission of control information (Fig. 3) by voltage at the terminals of phase A of the power source generates clock pulses with a frequency of 50 Hz, according to which information pulses of control messages are generated and received.

 At the end of the last section of the cascade (Fig. 1), on the phase A wire selected for one control channel, the control information transmission unit 9 generates control messages with a constant repetition period (Fig. 2), consisting of information pulses encoding the control information. At all switching points, the control device 18 (Fig. 3) monitors the operation of the cascade (power supply, protection elements, state of contactors) and the device 13 for receiving control parcels captures the control parcels at the beginning of the section of the cascade on register 19.

 At all switching points, except the executive switching point, the device 15 generates control messages on the control wire (phase A of Fig. 1) at the end of the previous section of the cascade, and on the executive switching point on the communication wires 8 (Fig. 1) with the control room.

 If at the switch-on point the control device 16 detects a malfunction or absence of control parcels in the cascade section, then the correction circuit 20 in the control parcel encodes the detected fault, including the absence of the control parcel, and the number of the switching point.

 In the example in FIG. 2, only the fact of a malfunction is encoded, by the fact of the presence of an information impulse, in the address field A. The type of malfunction detected can be encoded if a field of the type of malfunction is entered into the control message.

 If the control device 16 does not detect a malfunction at the switching point, then the correction circuit does not work and the control parcel generation circuit 15 transmits the contents of the control parcel received at the beginning of the cascade section.

 At the control room, control parcels are received from the executive switching point, and the cascade is judged by the contents of the information fields of the control parcels.

 At the end of each section of the cascade, the control device 16 controls the voltage on the control wire of the second channel and the correction device 20 encodes the presence of voltage on this wire in the control package. At each switching point, the combinational circuit 19 determines the correspondence of the voltage information in the control package to the voltage on the control wire of the second channel at the beginning of the cascade section. When the voltage mismatch at the output of the combinational circuit 19, a fault signal is generated such as a wire break, which is fed to one of the inputs of the control device.

 If in the control device of the cascade of outdoor lighting the transmission of control packages is made through the wires of two control channels, then at the beginning of the section of the cascade a combinational circuit connected at the inputs to the outputs of the registers 14 and control devices 16, and at the outputs with the inputs of the control devices 16 of the control and transmission units 10 control information, analyzes the situation: if there are no information pulses on the wire of one of the channels, but according to the control information of the other channel there is no discrepancy in the voltage on the wire of this channel la with the power, the combinational circuit detects the fault type hardware failure, if inconsistencies in voltage fault type wire breakage, in the absence of voltage on wire type violation fault control channel.

Claims (2)

 1. METHOD FOR EXTERNAL LIGHTING CASCADE CONTROL, which consists in the fact that at the end of the last section of the cascade on the wire selected for one control channel, control parcels are formed with a constant repetition period, the operation of the cascade is monitored at all switching points and the control parcels are recorded at the beginning of the cascade section , at all switching points, except for the executive one, they form on the control wire at the end of the previous section of the cascade, and at the executive switching point on the communication wires with the control center parcels; moreover, if at the switching-on point they do not detect a malfunction or lack of control parcels in the cascade section, then the detected parcel is encoded in the control parcel, including the absence of the control parcel, and the number of the switching point, if the switching point does not detect a fault, then the control parcel transmits the contents the control package received at the beginning of the section of the cascade, at the control room receive control packages from the executive point of inclusion and the contents of the information x fields of the control premises judge the operation of the cascade, characterized in that at the end of each section of the cascade the voltage on the control wire of the second channel is monitored and the voltage on this wire is encoded in the control package, at each switching point the information on the voltage in the control package matches the voltage to the control channel of the second channel at the beginning of the cascade section, in case of voltage mismatch, a "wire break" type fault is recorded.  2. The method according to claim 1, characterized in that the control information is transmitted through the wires of two control channels, and at the beginning of the cascade section, the situation is analyzed if there are no information pulses on the wire of only one of the channels, but there is no discrepancy in the control information of the other channel voltage on the wire of this channel when the voltage is on, then fix a failure of the type "hardware failure", if there is a mismatch in the voltage, a failure of the type "wire break", in the absence of voltage on the wire equality of type "wire breakage or equipment malfunction.

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