RU2726046C1 - Industrial objects electric heating monitoring system - Google Patents

Abstract

FIELD: heating.SUBSTANCE: invention relates to devices for electric heating of industrial facilities, such as pipelines, cisterns and similar hollow industrial facilities, the content of which requires heating. Technical result is obtained by the electric heating system monitoring device, containing the ABCN power supply first line, the QF6 breaker-splitter installed in it and the CM6 contactor, second power line ABCN connected through contactor KM6 to the first power supply line, to which controller K of electric heating system is connected, grounding electrical conductors PE, insulation monitoring relay RCT, current transformers TT1-TT3 and button switch SA1. RCT isolation monitoring relay is connected to grounding conductor PE of the second ABCN power supply line, CT1-TT3 current transformers are connected to the device between the QF6 tripping circuit breaker and the CM6 contactor, button switch SA1 is connected through switch-releaser QF7 to electric cables ABCN of the second line. Device incorporates throttle D and connected to it contactor KM7, contactors KM6 and KM7 are connected to electric cables ABCN of second power supply line. Controller K is connected to electric cables A and N of the first power supply line and to isolation monitoring relay of RCT, which is connected to grounding electrical conductors PE and throttle D. Device comprises electric power supply circuits of electric heating and in each power supply circuit contains electric conductors of loop power supply, PE grounding electrical conductor, as well as QF1-QFn automatic circuit breakers, FA1-FAn and KM1-KMn contactors electrically connected to electric cables ABCN of the second power supply line, which are in-series and electrically connected by cables.EFFECT: high reliability of the control device when realizing the disclosed solution.1 cl, 1 dwg

Description

This invention relates to devices for electric heating of industrial facilities, such as pipelines, tanks and similar hollow industrial facilities, the contents of which require heating.

A device is known to be used in electric heating systems of industrial facilities, comprising a power line with circuit breakers, contactors, an environmental reading station connected to a power line of the heating sections of the electric heating system (Z.I. Fonarev, “Wiring diagram for switching on the ENGLI-ISO”, Electric heating pipelines, tanks and technological equipment in the oil industry, L., "Nedra" Leningrad Branch, 1984, p. 62).

A device for detecting a ground fault of electric cables of an electrical system comprising a first and second electrical component and a controller is known from foreign patent documentation, while the second electrical component can be connected to the controller. An earth fault detection system may include an earth fault detection module integrated in the first electrical component. The first electrical component may be isolated from the second electrical component. The earth fault detection system may further include a data channel configured to establish data transmission between the controller and the earth fault detection module. The earth fault detection module may be configured to activate an operation mode for the first electrical component if an earth fault associated with the first electrical component is detected (US 2009219656 A1, September 3, 2009).

Also known is a control device for an electric heating system of an industrial facility, consisting of standardized modules that provide heating control and maintain a certain temperature of various objects in accordance with the device described in patent BY 2653 U, 04.30.2006. In this patent, the device comprises a housing in which electrical modules are located: a control and protection module, a connecting module, a temperature signal monitoring module. The connecting module is electrically connected to the control and protection module and contains a group of contacts for connecting an external power source and a group of contacts for connecting with heating means (heating cables, etc.). This device according to patent BY 2653 U is an analogue in which it is not possible to specify cascading control algorithms and means for the task of control algorithms. As follows from the description of BY 2653 U, one of the known drawbacks of self-regulating heating cables is a high starting current, significantly exceeding the rated operating current. This disadvantage is taken into account when designing and assembling electric heating control devices when calculating the mains supply and protective devices. The device according to BY 2653 U uses protective equipment designed for higher starting currents (exceeding the rated operating currents), which reduces the overall electrical safety and can lead, for example, to failure of the electric heating control device, or electric shock to personnel (BY 2653 U April 30, 2006).

A device for controlling an industrial heating system is known, comprising a housing, a control and protection module electrically connected to the connecting module, and a temperature signal monitoring module, the device further comprising an interface bus, a power metering module, comprising a computing device and configured to receive and transmit data from an external means of measuring electrical parameters, a communication module with the upper level, an indication module of the operation of the control unit of the industrial heating system and an external heating means, and a central control module comprising a computing device and configured to exchange signals with the communication module with the upper level and the indication module of the unit control system for industrial heating and external heating means, as well as through the aforementioned interface bus with control and protection module, temperature signal monitoring module, technical metering module electricity (RU 162719 U8, 06.27.2016).

A device for controlling the decrease in insulation resistance in the supply line of the supply voltage to the load, including a control signal generation circuit connected to a control line connected to a voltage divider, a memory device for storing the measured values of the control signal from the control line associated with the circuit for analyzing measurement results and an analysis result indication circuit, characterized in that the control signal generating circuit includes a main supply voltage source connected to a supply voltage supply line to a load, and an additional voltage source connected to a minus terminal with a plus terminal of the main source through a switching device connected an output to the positive terminal of a zener diode connected by a negative terminal to the positive terminal of an additional source and to the input of a voltage divider connected by an output to a circuit for analyzing the measurement results, consisting of sequentially the analog-to-digital converter, a storage device, a computing device and a comparison circuit, the output of which is connected to an indication circuit (RU 2381513 C1, 02/10/2010).

A device for monitoring the insulation of a DC network with an isolated neutral for implementing the method, comprising a bridge circuit formed by resistors and insulation resistances, one of the diagonals of which is connected to the poles of a DC network, differential DC sensors for measuring currents for each connection, containing an annular magnetic circuit, comprising one turn of the “plus” and “minus” connection wires, as well as a measuring winding connected to the measuring circuit, connected to the interface, moreover, characterized in that an additional resistor is included in the other diagonal of the bridge circuit, and the bridge circuit is made with the possibility of alignment voltage at the poles of the DC source, while the device contains two voltage divider containing two series-connected resistors, connected between the "ground" and the positive and negative poles of the DC source using controlled keys, in addition, the device further comprises a differential DC sensor for measuring the current flowing through an additional resistor and voltage dividers, the interfaces being connected to the first input of the information processing unit, one output of which is connected to a reading device, and the other two to the control inputs of the keys, to the second input the information processing unit is connected to the output of an analog-to-digital converter, the inputs of which are connected to common connection points of the resistors of each voltage divider (RU 2313799 C1, 12.27.2007).

A known high-voltage system containing several high-voltage components, which are, respectively, under high electric voltage, several devices for measuring insulation resistance, made, respectively, with the ability to measure insulation resistance between one of the high-voltage components and the mass, at least one resistance control unit isolation of high-voltage components, and an annular control line is provided, which comes from the control unit and sequentially connects it to the individual high-voltage components and then returns to the control unit, which is configured to transmit a polling signal through the ring-shaped control line, and the control unit is configured to check, the acceptance of the polling signal transmitted by the control unit after passing the annular control line again by the control unit, the control unit being configured to turn off high-voltage components if the control signal does not receive a polling signal, and the device is characterized in that the insulation measuring devices are capable of measuring the insulation resistance continuously at short time intervals of less than 90 seconds, the control unit is configured to turn off high-voltage components if the measured insulation resistance falls below a predetermined minimum values, the high-voltage components are interconnected via high-voltage lines, the control line is drawn through the high-voltage lines, so that the control line is interrupted when at least one of the high-voltage lines is open (RU 2620364 C2, 05.25.2017).

A control device is known that contains a low-voltage transformer of a mains power supply, an electric circuit, sequentially directly disconnected means, resistors for calibrating the short-circuit current and voltage drop allowed at the terminals of the signaling devices, which are light-emitting diodes or buzzers, while it has a control switch for driving into the action of the signaling device to check the operability of the transformer and / or the integrity of at least part of the electrical circuit, that the signaling device to check the operability is a direct disconnect means consisting of one or more resistors, directly through which the short circuit current generated due to deterioration of the insulation capacity of one or several adjacent insulating layers, while the passage of a short circuit current through one or more resistors, they heat the thermosensitive elements electromechanically thermal protection device for controlling the resistance with multilayer insulation until the thermal protection device is triggered, while in the device the direct disconnecting means consist of transmitting means for transmitting a signal to the electronic thermostat for monitoring resistance with multilayer insulation, causing the thermal protection of the electronic thermostat to trip, while the signal is initiated by a short circuit current, the transmitting device compatible with the electronic thermostat consists of an optical isolator, through the LED of which a short circuit current can be directly circulated, while a calibration resistor is connected in series with the LED of the optical insulator, while the means of direct disconnection consist of a two-position relay, having a first and second coil capable of opening / closing a switch, a restart button, a closing switch that drives the first coil, and the switch is configured to open all resistance phases with multilayer insulation (RU 2577386 C2, 03.20.2016).

A control device for an electric network is known, characterized in that it includes means for detecting electric signals (S1) and additional signals (S2) generated in the electric network (3), additional signals (S2) are of a physical nature different from electric signals (S1) , the device contains means for processing said electrical signals to determine a first time reference (t1) representing the moment of detection of electric signals emitted when a malfunction event (E) occurred in the electric network, the device has means for processing said additional signals (S2) for determining a second time reference point (t2) representing the moment of detection of additional signals emitted when the mentioned malfunction event occurred in the electric network, and it also has processing means for spatial localization of the mentioned malfunction event in the electric network, depending on the first and second time reference points (t1, t2). Said processing means are configured to determine the first and second time references by applying a signal processing analysis to said electrical signals and said additional signals, respectively, said processing analysis being selected from the following processing technologies: wavelet transform processing, Fourier processing and Wigner-Ville processing. Said processing means are configured to apply analysis using a discrete wavelet transform, to perform cartography identifying the localization of normal non-linear loads in the aforementioned electrical network and to recognize an actual failure event with respect to an event caused by a normal non-linear load identified in said cartography. Said processing means are configured to determine values related to numerical failure coefficients, compare said values with critical thresholds, and cause an immediate shutdown when one of the said values exceeds a critical threshold, to record a set of cases of malfunctions. The detection means include first detection means of said electrical signals and second detection means of said additional signals, said first and second detection means are installed at the same geographical location at the input of the electric network, said additional signals being mechanical wave signals (RU 2631492 C1, 05.25.2017).

Of the known devices, the closest device to the monitoring device presented in this description is a known device for the automated control of the electrical strength of insulation, comprising a housing with a cover, a control and monitoring unit (BUC) in the form of a microcontroller (MK), a keyboard (CL) and a liquid crystal display (LCD) ), a high-voltage voltage switching unit (BKVN) with a relay (RL) and a breakdown sensor (DP), a connector block (BS) with switching elements (CE), an external power supply unit (BEP), an internal power supply (IWEP) and a high-voltage test source voltage (IVIN), characterized in that the BUK is equipped with a converter (KB) and a signal processing module (MOS), BKVN is equipped with the first and second switches (KM), the DP is made in the form of a high-voltage optocoupler (VOP) and a current-limiting resistor (TOR), and BS is equipped with two high-voltage buses (VS) "A" and "B", while the input of the BVEP is connected to the industrial voltage network, the first output of the BVEP is connected inen with the input of the IWEP, and the second output of the BEWP with the input of the IWIN, the output of the IWEP through the first input of the BUK is connected to the input KB, the first output of which is connected to the first input of the MK, the second output of KB is connected through the first output of the BUK to the first input of the BKVN, the output of the CL with the third MK input, the second MK output is connected to the LCD input, and the third MK output through the second BUK output is connected to the second BKVN input, the first and second BKVN inputs are connected respectively to the first and second radar inputs, the first and second radar outputs to the first inputs the first and second KM, the second inputs of which are connected respectively through the fourth and fifth inputs of the BKVN with the first and second outputs of the IVIN, and the outputs of the first and second KM through respectively the first and second outputs of the BKVN are connected with the first and second inputs of the BS and, respectively, through the VS “A” and “B” - with the first and second inputs of each FE, in addition, the second inputs of each FE are connected to each other and through the first output of the BS - with the third input of the BKVN and, accordingly, with the input of the TOP, which is the input of the DP, the output d TOP is connected to the input of the VOP, whose output, which is the output of the DP through the third output of the BKVN, is connected to the second input of the BUK and, accordingly, to the input of the MOS, the output of which is connected to the second input of the MK, and KB, RL and MOS form the first stage of galvanic isolation (GR ) KL and ZhKI from electric circuits of BVEP and IVIN, and the first and second KM and DP - the second stage of GR, BVEP and IVEP provide power to the component parts of the device, and IVIN - the necessary test voltage. The case is equipped with a limit switch (KVK), which, when the cover of the case is lifted, opens the circuit and removes the high-voltage voltage from the BS CE, while the input of the KVK is connected through the cover, the case and the third output of the BUK with the third output KB, the first output of the KBK through the third input of the BUK is connected to the fourth input of the MK, and the second output of the KVK - with the grounding bus of the housing. The BUK includes an audible signaling device (ZS) of the end of control in case of insulation compliance with technical specifications or fixing a breakdown of insulation of the tested product, while the input of the ZS is connected to the first output of the MK, as well as the first, second, third and fourth voltage indicators (IN) of the presence of high-voltage the voltage at the outputs of the IVIN and at the inputs of the CE BS, while the inputs of the first and second IN are connected respectively to the first and second outputs of the IVIN, and the inputs of the third and fourth IN are connected respectively through the second and third outputs of the BS and VS “A” and “B” with CE (RU 166053 U1, 11/10/2016 - prototype).

In terms of the claimed device with common features with the prototype, the control device presented in this description has such signs that the control device for the electric heating system of industrial facilities contains a first power supply line ABCN, a QF6 switch-disconnector and a contactor KM6 installed in it, a second power supply line ABCN connected through KM6 contactor with the first power line to which the electric heating system controller K is connected, PE grounding conductors, RCT insulation isolation relay, TT1-TT3 current transformers and SA1 push-button switch.

In the design of the prototype there are many other elements that, together with the essential features of the device, represent a relatively complex design, while the complexity of the design, depending on the number of its elements and the connections between them, negatively affects the reliability of control due to the summation of the errors received from the elements and the connections between them .

The technical result of the invention presented in this description is to increase the reliability of control.

The technical result was obtained by a device for monitoring an electric heating system of industrial facilities, containing a first power line ABCN, a circuit breaker-release QF6 and a contactor KM6 installed in it, a second power line ABCN connected through a contactor KM6 to a first power line to which an electric heating system controller K is connected, electrical conductors PE grounding, RCTI insulation monitoring relay, TT1-TT3 current transformers and SA1 push-button switch, with RCTI insulation monitoring relay connected to the PE grounding conductor ABCN of the second power line, TT1-TT3 current transformers are connected to the device between the QF6 circuit breaker and contactor KM6, the push-button switch SA1 is connected via a circuit breaker-release QF7 with electric cables ABCN of the second line, while the inductor D and the contactor KM7 connected to it are inserted into the device, while the contactors KM6 and KM7 are connected to the electric cables ABC of the second power line, the controller K is connected to the power cables A and N of the first power line and with an RCI insulation control relay that is connected to the PE ground conductors and the inductor D, the device contains power supply circuits for electric heating and each power supply circuit contains power supply conductors for the circuit, PE ground conductor, and also consecutively located and the QF1-QFn circuit breakers electrically connected by cables, the FA1-FAn fuses and the KM1-KMn contactors electrically connected to the ABCN electric cables of the second power line.

In FIG. 1 shows one example of a control device for an electric heating system for industrial facilities. The device is implemented on the basis of such elements and the connections between them that are used in the construction of piping electrical heating systems for oil transportation.

The device comprises a first power supply line 1 ABCN, having a circuit breaker 2 (QF6) and a contactor 39 (KM6) included therein, the latter being connected to power cables ABCN of the first line 1 and to power cables ABCN of the second power supply line 9. Contactor 39 (KM6) is electrically connected to switch 2 (QF6).

The device comprises a controller 3 (K) connected to electric cables A and N of the first power supply line 1. The controller 3 is made programmable and logistic, or it can be made different, providing the specified control functions.

The current transformers 4,5 and 6 (TT1, TT2 and TT3) are connected to the first power supply line 1, respectively connected to the ABC power cables of the first power supply line 1. The current transformers of the device are connected by electric wires 7 to their corresponding current measuring devices 8 (PA1, PA2 and PA3), for example, ammeters. Electrical cables ABCN of the first line 1 are connected to the electrical conductors ABCN of the second (linear) power supply line 9.

The control device contains a relay 10 insulation control (RCT), connected to a protective electrical conductor 31 ground (PE) of the second power line 9 and the inductor 36 (D). The device contains circuits 11-15 power supply means for electric heating of industrial facilities. The number of circuits depends on the number of means for electric heating, or on the number of heated sections of the pipeline, or on the number of individual pipelines included in a single system of electric heating of many objects.

In this embodiment, metal tubular elements mounted on the pipeline with electric cables located in them (not shown), forming eddy currents interacting with each other, heating tubular elements and sections of an extended pipeline, are used as electric heating means.

The power supply circuit 11 has an electric conductor A and N connected to the electric conductor A and N of the second power line 9, and the circuit 11 has a trip switch or circuit breaker 16 (QF1) and a contactor 17 (KM1), between which there is a residual current circuit breaker connected to them - fuse 18 (FA1).

The power supply circuit 12 has conductors B and N connected to the conductors B and N of the second power supply line 9, the circuit 12 having a trip switch or circuit breaker 19 (QF2) and a contactor 20 (KM2) between which a residual current circuit breaker is connected - fuse 21 (FA2).

The power supply circuit 13 has conductors C and N connected to the conductors C and N of the power line of the second power supply line 9, the circuit 13 having a trip switch 22 (QF3) and a contactor 23 (KM3), between which there is a residual current circuit breaker connected to them - a fuse 24 (FA2).

The power supply circuit 14 has an electrical conductor A and N connected to the electrical conductors A and N of the second power supply line 9, the circuit 14 having a trip switch or circuit breaker 25 (QF4) and a contactor 26 (KM4) between which a residual current circuit breaker is connected - fuse 27 (FA4).

The power supply circuit 15 has conductors B and N connected to the conductors B and N of the second power supply line 9, the circuit 15 having a trip switch or circuit breaker 28 (QF5) and a contactor 29 (KM5), between which a residual current circuit breaker is connected - fuse 30 (FA5).

The power supply circuits 11-15 of the electric heating means have grounding conductors (PE) 31 and these grounding conductors 31 are connected to one ground line with grounding conductors (PE) 31 of the second power supply line 9.

The control device comprises a push-button switch 32 (SA1), a voltmeter 33 (PV1) connected to it and an automatic release switch 34 (QF7) connected to the switch 32.

Said power lines 11-15 are connected to electric heating objects 35, which, in this example of the device, are sections of an oil pipeline.

A contactor 37 (KM7) is inserted into the above-described device, connected by electric wires to said inductor 36 (D) and to electric cables ABC of the second power supply line 9. Position 38 in the diagram (Fig. 1) conventionally shows the tire section (SS).

The above-mentioned contactor 39 (KM6) connected to the ABCN power cables of the first power supply line 1 and to the ABCN power cables of the second power supply line 9 is also introduced into the device described above. Electrical cables A and N of the first power supply line 1 are connected to the insulation control relay 10 (RCT) and the controller 3 (K). The relay 10 is also connected to the ground conductors 31 (PE) and to the inductor 36 (D).

The power supply circuits 11-15 of the electric heating facilities of the facilities 35 are connected by electrical wires to the ABCN power cables of the second power supply line 9. Each circuit is electrically and mechanically connected to its corresponding object of electric heating 35, in particular with a pipeline. Each circuit contains electrical conductors for the power supply of the circuit, grounding conductor PE, as well as QF1-QFn circuit breakers, fuses FA1-FAn and contactors KM1-KMn, which are electrically connected to the ABCN electric cables of the second power line, and are serially arranged and electrically connected by cables.

The presented diagram shows an example of a device containing the power supply circuits 11-15 for electric heating of industrial facilities 35 using the electric heating of pipe sections as an example. The device may comprise a single power supply circuit of one electric heating means or a plurality of power supply circuits of a plurality of electrical heating means, the number of such circuits depending on the number of electric heating objects.

In this regard, in the circuit diagram of the device, the above-mentioned elements of the device can be generally represented as circuit breakers-releases QF1-QFn, fuses FA1-FAn and contactors KM1-KMn, where n is the next number of the element of the device after the first.

The device operates as follows. To monitor the insulation resistance of the system to the specified load, turn on the circuit breaker 2 (QF6).

In this case, the controller 3 (K) and the relay 10 insulation control (RCT) receives operational power supply (Uonep). In this case, in the relay 10 (RCT), the alternating current (Uonep) is converted to direct current (by means of a rectifier unit, for example, a diode bridge) and through the inductor 36 (D), direct current is supplied through the electric wires to the terminals of the contactor 37 (KM7). At the same time, controller 3 (K) is initiated and the procedure for monitoring insulation resistance is called before turning on the electric heating system of industrial facilities.

After the operations, the controller 3 (K) includes a contactor 37 (KM7) and a constant voltage is supplied to the second ABC power line 9 in the bus section 38 (SS). In this case, in the event of an accident, - insulation malfunction, - the "Alarm" signal is read from the insulation control relay 10 (RCT).

In the presence of the “Alarm” signal, the “Alarm” lamp turns on and the indication in the controller menu 3 - “Alarm in the bus section (SS)”. In this case, the insulation resistance monitoring before turning on the heating system is terminated, since normal operation is not possible until the fault is eliminated in section 38 of the busbar (SS).

Next, the controller 3 turns off the contactor 37 (KM7). In case of serviceability, in section 38 of the bus (SS), controller 3 includes contactors 17, 21, 23, 27 and 29 (KM1-KM5) and the Alarm signal is read from the insulation control relay 10 (RCT). If the electrical wires A, B, C, N of circuits 11-15 of the electrical wiring of the facilities 35 are in good condition, the insulation resistance control to the load before switching on the heating system is considered complete. After that, the controller 3 turns off the contactor 37 (KM7) and the controller 3 turns on the contactor 39 (KM6). In this case, the operating mode of the heating system is set.

In the presence of the "Alarm" signal received from the insulation control relay 10 (RCT), faulty power supply circuits 11-15 are searched for by means of electric heating, while the controller turns off the contactors 17, 21, 23, 27 and 29 (KM1-KM5) and turns on the contactor 17 (KM1). After that, they control the insulation resistance before turning on the first circuit 35 (circuit 1) of electric heating.

In case of good insulation, the controller 3 (K) disconnects the contactor 17 (KM1) and the first electric heating circuit 11 and turns on the next contactor 21 (KM2) of the electric heating circuit 12. The described algorithm of actions is repeated until the last circuit 15 of the electric heating is turned on.

If a faulty circuit is detected, the faulty circuit is turned off by the corresponding circuit breaker (QF1 ... QF5), and the "Alarm" lamp is turned on and the indication in the controller menu 3 indicates a insulation fault in the corresponding circuit.

After controlling the insulation resistance of all circuits, the controller 3 (K) includes contactors 17, 21, 23, 27 and 29 (KM1-KM5) of serviceable power circuits. Next, the controller 3 turns off the contactor 37 (KM7) and control the insulation resistance before turning on the heating system is considered complete. Controller 3 includes a contactor 39 (KM6), after which it is turned on, the operating mode of the electric heating system of industrial facilities is established.

For circuit breakers (QF1 ... QF5) with the signal "Status QF1 ... QF5 off", set the flag that the check has not been performed. The operating modes “on”, “off” or “automatic” are selected through the menu of the controller 3.

The control device has a relatively simple design, which positively affects the reliability of its operation. This is achieved due to the fact that the reduction in the number of elements of the device reduces, accordingly, the possibility of obtaining cumulative errors in determining the safety of insulation of elements of the electric heating system.

At the same time, the use of elements of the electric heating system as elements of a control device made it possible to create the simplest design of the control device and increase the reliability and reliability of data on the state of the electric heating system of industrial facilities.

Claims (1)

A control device for the electric heating system of industrial facilities, containing the first ABCN power line, the QF6 circuit breaker and contactor KM6 installed in it, the second ABCN power line connected through the KM6 contactor to the first power line to which the electric heating system controller K is connected, PE grounding conductors, RCTI insulation control relay, TT1-TT3 current transformers and SA1 push-button switch, characterized in that RCTI insulation control relay is connected to the grounding conductor PE of the second power supply line ABCN, current transformers TT1-TT3 are connected to the device between the QF6 circuit breaker and contactor KM6, the push-button switch SA1 is connected via a circuit breaker-QF7 to the second-line power cables ABCN, the choke D and the contactor KM7 connected to it are inserted into the device, while the contactors KM6 and KM7 are connected to the power cables ABC of the second power line, the controller K is connected to the power cables A and N of the first power line and with an RCI insulation control relay that is connected to the PE ground conductors and the inductor D, the device comprising power supply circuits of the electric heating means and each power supply circuit contains power supply circuits of the circuit, PE ground conductor, and also series-connected and electrically connected cable breakers QF1-QFn, fuses FA1-FAn and contactors KM1-KMn, electrically connected to power cables ABCN of the second power line.

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