CN215215776U - Online diagnosis device for main steam isolation valve of nuclear power plant - Google Patents

Abstract

The utility model particularly relates to a nuclear power plant main steam isolating valve online diagnosis device, which comprises a sensor unit, a signal detection unit, a data processing unit and an upper computer; the sensor unit, the signal detection unit, the data processing unit and the upper computer are in communication connection in sequence; the sensor unit is mechanically connected with a main steam isolation valve of a nuclear power plant. The utility model discloses a nuclear power plant main steam isolating valve on-line diagnosis device and method synthesizes on-line measuring and fault diagnosis technique, does not dismantle at the valve, under the prerequisite of not disassembling, carries out on-line diagnosis test to main steam isolating valve comprehensive properties.

Description

Online diagnosis device for main steam isolation valve of nuclear power plant

Technical Field

The utility model relates to a nuclear power plant owner steam isolating valve online diagnosis technical field especially relates to a nuclear power plant owner steam isolating valve online diagnosis device.

Background

A main steam isolation valve of a nuclear power plant belongs to key sensitive equipment, the valve is quickly closed within 5s under accident conditions such as steam pipeline breakage, once the valve breaks down during operation, important events such as unit shutdown and the like can be caused, and the main steam isolation valve is a key important valve of the nuclear power plant. The valve is large in size and weight, driven by a gas-liquid linkage executing mechanism, multiple in hydraulic equipment, complex in control system, multiple in valve working modes (fast closing, slow closing, full opening and full opening maintaining), lack of an online diagnosis device, and difficult to comprehensively master and evaluate the performance state.

SUMMERY OF THE UTILITY MODEL

Therefore, in order to solve the above problems, it is necessary to provide an online diagnosis device for a main steam isolation valve of a nuclear power plant, which integrates online detection and fault diagnosis technologies and performs online diagnosis and test on the comprehensive performance of the main steam isolation valve on the premise that the valve is not detached and disassembled.

In order to achieve the above object, the present invention provides the following technical solutions:

a nuclear power plant main steam isolation valve online diagnosis device comprises a sensor unit, a signal detection unit, a data processing unit and an upper computer; the sensor unit, the signal detection unit, the data processing unit and the upper computer are in communication connection in sequence; the sensor unit is mechanically connected with a main steam isolation valve of a nuclear power plant.

The sensor unit collects characteristic signals of various parameters to be detected of a main steam isolation valve of a nuclear power plant and sends the characteristic signals to the signal detection unit, the signal detection unit receives signals sent by the sensor unit and sends the processed signals to the data processing unit, the data processing unit receives the signals sent by the signal detection unit and sends the signals to the upper computer after analog-to-digital conversion is carried out on the signals, and the upper computer receives the signals sent by the data processing unit and carries out online diagnosis on the signals.

Further, the sensor unit includes a displacement sensor, a switching value sensor, a stress sensor, a micro-current sensor, a current sensor, and a voltage sensor; the moving part of the displacement sensor is arranged on the valve rod; the switching value sensor is connected with a normally open contact or a normally closed contact of the limit switch; the stress sensor is fixedly arranged at the polished rod part of the valve rod; the micro-current sensor is respectively arranged on signal output cables of the nitrogen pressure transmitter and the oil pressure transmitter, and on power supply cables of a pump side main electromagnetic valve, a pump side test electromagnetic valve, a non-pump side main electromagnetic valve and a non-pump side test electromagnetic valve of a hydraulic control loop in the hydraulic control loop; the current sensors are respectively arranged on three-phase power lines of an oil pump motor of the hydraulic control loop; the voltage sensor is arranged at the power supply input port of the oil pump motor in the hydraulic control loop and is in point-to-point corresponding conduction with the three-phase power supply.

Furthermore, the displacement sensor is a pull-wire type displacement sensor, the switching value sensor is a multi-channel switching value sensor, the stress sensor is a patch type stress sensor, the micro-current sensor is a non-contact micro-current sensor, the current sensor is a non-contact current sensor, and the voltage sensor is a three-phase voltage sensor.

Further, the signal detection unit includes displacement signal detection unit, logic signal detection unit, strain signal detection unit, little current signal detection unit and power detection unit, current sensor and voltage sensor are connected with the power detection unit communication respectively, the on-off quantity sensor is connected with logic signal detection unit communication, displacement sensor and displacement signal detection unit communication are connected, the stress sensor is connected with strain signal detection unit communication, little current sensor and little current signal detection unit communication are connected, displacement signal detection unit, logic signal detection unit, strain signal detection unit, little current signal detection unit and power detection unit are connected with the data processing unit respectively.

Furthermore, the online diagnosis device for the main steam isolation valve of the nuclear power plant further comprises a power module and a management unit, wherein the power module and the management unit are respectively and mechanically connected with the sensor unit, the signal detection unit and the data processing unit, and meanwhile, the power module and the management unit are in communication connection with the data processing unit through serial ports.

The data processing unit receives the battery condition information sent by the power supply module and the management unit and sends the battery condition information to the upper computer, and the upper computer sends an information acquisition starting/stopping instruction to the data processing unit to control the starting or stopping of data acquisition. Specifically, the upper computer sends an information acquisition starting instruction to the data processing unit, the data processing unit sends a charging instruction to the power module and the management unit, the power module and the management unit provide direct current power for the sensor unit, the signal detection unit and the data processing unit, and information acquisition is started; the upper computer sends an information acquisition stopping instruction to the data processing unit, the data processing unit sends a discharging instruction to the power supply module and the management unit, the power supply module and the management unit stop providing direct current power for the sensor unit, the signal detection unit and the data processing unit, and information acquisition stops.

Further, valve diagnosis software is installed on the upper computer, and the valve diagnosis software completes online diagnosis of the main steam isolation valve of the nuclear power plant.

Furthermore, the online diagnosis is to compare and analyze the measured value of the parameter to be monitored measured by the sensor unit with the allowable range of the theoretical value of the parameter to be detected, so as to obtain a diagnosis conclusion.

The utility model has the advantages of:

the utility model discloses a nuclear power plant owner steam isolating valve online diagnosis device can carry out diagnostic test to this valve comprehensive properties during the unit is shut down under the prerequisite that main steam isolating valve was not dismantled and is disintegrated, through travel time and the atress condition when monitoring the different actions of valve, draws relevant characteristic parameter to the analysis reachs comprehensive properties such as valve action performance, sealing performance.

The utility model discloses an online diagnostic device of nuclear power plant main steam isolating valve, online diagnostic analysis conclusion can guide the maintenance personal to adjust the valve to the optimum condition, carry out the state performance to the main steam isolating valve after the maintenance simultaneously and verify, effectively avoid human error to guide follow-up maintenance work (promptly state maintenance), so that take the trouble of pertinence measure to this valve to carry out analysis and processing, ensure that the experiment is once only passed through after the valve maintenance, the operator fit time that significantly reduces.

The utility model discloses a nuclear power plant main steam isolating valve online diagnosis device, through the accumulation of main steam isolating valve online diagnosis data, the analysis goes out the performance degradation trend, arranges maintenance work before its trouble takes place, avoids relevant accident and loss to take place, makes the maintenance opportunity predictability of main steam isolating valve, the maintenance effect can be verified, improves main steam isolating valve state management level and nuclear power plant's safe economic operation index.

The utility model discloses a nuclear power plant owner steam isolating valve online diagnosis device is applicable to the similar main water supply isolating valve online diagnosis of nuclear power plant equally.

Drawings

FIG. 1 is a schematic structural view of a main steam isolation valve online diagnosis device of the present invention;

fig. 2 is a schematic structural view of the main steam isolation valve of the present invention.

In the figure, 1, a sensor unit; 2. a signal detection unit; 3. a data processing unit; 4. a power module and a management unit; 5. an upper computer; 6. a hydraulic control circuit; 7. an actuator; 8. a valve stem; 9. a yoke; 10. a valve body; 11. a nitrogen pressure transmitter; 12. an oil pressure transmitter; 13. a limit switch; 101. a displacement sensor; 102. a switching value sensor; 103. a stress sensor; 104. a micro-current sensor; 105. a current sensor; 106. a voltage sensor; 201 displacement signal detection unit; 202. a logic signal detection unit; 203. a strain signal detection unit; 204. a micro-current signal detection unit; 205. and a power detection unit.

Detailed Description

The nuclear power plant main steam isolating valve comprises a valve body 10, a valve rod 8, a yoke 9, an executing mechanism 7, a hydraulic control loop 6, a limit switch 13, an oil pressure transmitter 12 and a nitrogen pressure transmitter 11, wherein the executing mechanism 7 is used for providing power for the vertical direction movement of the valve rod 8, the valve rod 8 is connected with a valve clack inside the valve body 10, and the sealing state of the valve can be changed by changing the position of the valve clack in the vertical direction, so that the opening, closing and other actions of the valve are realized. The hydraulic control circuit 6 is used for controlling the direction and pressure of oil pressure and then changing the position and motion state of the valve rod 8, thereby controlling the opening and closing state and the opening/closing process of the valve.

The utility model provides a nuclear power plant main steam isolating valve online diagnosis device, including sensor unit 1, signal detection unit 2, data processing unit 3, power module and management unit 4 and host computer 5, sensor unit 1, signal detection unit 2, data processing unit 3 and host computer 5 are the communication connection in proper order; the sensor unit 1 is mechanically connected with a main steam isolation valve of a nuclear power plant; the power module and the management unit 4 are respectively mechanically connected with the sensor unit 1, the signal detection unit 2 and the data processing unit 3, and meanwhile, the power module and the management unit 4 are in communication connection with the data processing unit 3 through a serial port.

The sensor unit 1 collects characteristic signals of various parameters to be detected of a main steam isolation valve of a nuclear power plant and sends the characteristic signals to the signal detection unit 2; the signal detection unit 2 receives the signal sent by the sensor unit 1, conditions the signal and sends the conditioned signal to the data processing unit 3; the data processing unit 3 receives the signal sent by the signal detection unit 2, performs analog-to-digital (namely A/D) conversion on the signal and sends the signal to the upper computer 5; the upper computer 5 receives the signals sent by the data processing unit 3 and carries out online diagnosis on the signals, including real-time display, curve drawing, characteristic value calculation and diagnosis analysis of characteristic signals of various parameters.

The data processing unit 3 receives battery condition information (battery power level information, charging and discharging information, abnormal conditions and the like) sent by the power module and management unit 4 and sends the information to the upper computer 5, and the upper computer 5 sends an information acquisition start/stop instruction to the data processing unit 3 to control the start or stop of data acquisition. Specifically, the upper computer 5 sends an information acquisition starting instruction to the data processing unit 3, the data processing unit 3 sends a charging instruction to the power module and management unit 4, the power module and management unit 4 provides direct current power for the sensor unit 1, the signal detection unit 2 and the data processing unit 3, and information acquisition is started; the upper computer 5 sends an information acquisition stop instruction to the data processing unit 3, the data processing unit 3 sends a discharge instruction to the power module and management unit 4, the power module and management unit 4 stops providing direct-current power for the sensor unit 1, the signal detection unit 2 and the data processing unit 3, and information acquisition stops.

Further, the data processing unit 3 is connected with the upper computer 5 through ethernet or WIFI.

Further, the sensor unit 1 includes a displacement sensor 101, a switching amount sensor 102, a stress sensor 103, a micro-current sensor 104, a current sensor 105, and a voltage sensor 106;

the displacement sensor 101 is a pull-wire type displacement sensor, and a moving part of the pull-wire type displacement sensor is arranged on the valve rod 8, keeps parallel and synchronous action with the valve rod 8 and is used for measuring the action stroke of the valve;

the switching value sensor 102 is a multi-channel switching value sensor, and the multi-channel switching value sensor is connected with a normally open contact or a normally closed contact of the limit switch 13 and is used for measuring the action logic of the valve limit switch;

the stress sensor 103 is a patch type stress sensor which is fixedly mounted on a polished rod part of the valve rod 8 by using special glue and acts together with the valve rod 8 of the main steam isolation valve of the nuclear power plant, and is used for measuring parameters such as valve closing force, seat separating force, inverted sealing force, friction force and the like;

the micro-current sensor 104 is a non-contact micro-current sensor, 2 non-contact micro-current sensors are respectively arranged on signal output cables of the nitrogen pressure transmitter 11 and the oil pressure transmitter 12 in a clamping manner, 4 non-contact micro-current sensors 104 are respectively arranged on power supply cables of a pump side main electromagnetic valve of the hydraulic control circuit 6, a pump side test electromagnetic valve of the hydraulic control circuit 6, a non-pump side main electromagnetic valve of the hydraulic control circuit 6 and a non-pump side test electromagnetic valve of the hydraulic control circuit 6 in a clamping manner, is used for measuring the output current of the nitrogen pressure transmitter 11 and the output current of the oil pressure transmitter 12, the output current of the nitrogen pressure transmitter 11 and the output current of the oil pressure transmitter 12 can be converted to obtain the actual values of the nitrogen pressure and the oil pressure, testing coil currents of the main electromagnetic valve and the test electromagnetic valve through the micro-current sensor 104, and obtaining action logics of the main electromagnetic valve and the test electromagnetic valve;

the current sensor 105 is a non-contact current sensor, and 3 non-contact current sensors are respectively installed on a three-phase power line of an oil pump motor of the hydraulic control loop 6 in a clamp type and used for testing the current of the oil pump motor of the valve;

the voltage sensor 106 is a three-phase voltage sensor, is installed at an input port of the oil pump motor power supply of the hydraulic control circuit 6, is in point-to-point corresponding conduction with the three-phase power supply, and is used for testing the voltage of the valve oil pump motor.

Further, the signal detection unit 2 includes a displacement signal detection unit 201, a logic signal detection unit 202, a strain signal detection unit 203, a micro-current signal detection unit 204 and a power detection unit 205, the current sensor 105 and the voltage sensor 106 are respectively in communication connection with the power detection unit 205, the switching value sensor 102 is in communication connection with the logic signal detection unit 202, the displacement sensor 101 is in communication connection with the displacement signal detection unit 201, the stress sensor 103 is in communication connection with the strain signal detection unit, the micro-current sensor 104 is in communication connection with the micro-current signal detection unit 204, and the displacement signal detection unit 201, the logic signal detection unit 202, the strain signal detection unit 203, the micro-current signal detection unit 204 and the power detection unit 205 are respectively connected with the data processing unit 3.

Further, valve diagnosis software is installed on the upper computer 5, and the valve diagnosis software completes online diagnosis of the main steam isolation valve of the nuclear power plant, including real-time display, storage, curve drawing, characteristic value calculation, diagnosis analysis and the like of characteristic signals of various parameters.

The utility model discloses a nuclear power plant owner steam isolating valve on-line diagnosis device, through the each item parameter characteristic signal of gathering nuclear power plant owner steam isolating valve in real time, including the performance parameter under the different mode of valve (fast switch, slow switch, open, keep opening wide), extract relevant characteristic parameter to comprehensive properties states such as diagnostic analysis goes out valve action performance, sealing performance and oil pump motor performance.

Use the utility model discloses a nuclear power plant main steam isolating valve during on-line diagnosis device, including following step:

the method comprises the following steps: and selecting parameters to be monitored of a main steam isolation valve of the nuclear power plant. A main steam isolation valve of a nuclear power plant belongs to a switch valve, and whether the main steam isolation valve can normally operate is evaluated mainly through action performance and sealing performance. The parameters to be monitored of the main steam isolation valve of the nuclear power plant are mainly considered from the two aspects. The parameters to be monitored related to the action performance comprise: pump side fast closing time, non-pump side fast closing time, double-side fast closing time, opening time, slow closing time, nitrogen pressure, oil pressure and the like; the parameters to be monitored relating to the tightness include: travel, closing force, unseating force, reverse sealing force, friction, etc.

Step two: and (4) determining the allowable theoretical value range of each parameter to be monitored selected in the step one when the valve is kept in normal operation. The method comprises the following steps that theoretical value ranges of parameters such as pump side fast closing time, non-pump side fast closing time, double-side fast closing time, opening time, slow closing time and stroke allowed by normal operation are obtained by inquiring design files of a main steam isolation valve; the theoretical value ranges of the closing force, the seat separating force, the reverse sealing force, the friction force, the nitrogen pressure and the oil pressure which are allowed by normal operation are obtained through calculation of the operating condition and the design parameters of the valve.

Step three: and (5) installing the corresponding sensor unit 1 according to the parameters to be monitored selected in the step one.

The sensor used for measuring each parameter to be monitored comprises: a displacement sensor 101, a switching value sensor 102, a stress sensor 103, a micro-current sensor 104, a current sensor 105, and a voltage sensor 106;

the displacement sensor 101 is a pull-wire type displacement sensor, and a moving part of the pull-wire type displacement sensor is arranged on the valve rod 8, keeps parallel and synchronous action with the valve rod 8 and is used for measuring the action stroke of the valve;

the switching value sensor 102 is a multi-channel switching value sensor, and the multi-channel switching value sensor is connected with a normally open contact or a normally closed contact of the limit switch 13 and is used for measuring the action logic of the valve limit switch;

the stress sensor 103 is a patch type stress sensor which is fixedly mounted on a polished rod part of the valve rod 8 by using special glue and acts together with the valve rod 8 of the main steam isolation valve of the nuclear power plant, and is used for measuring parameters such as valve closing force, seat separating force, inverted sealing force, friction force and the like;

the micro-current sensor 104 is a non-contact micro-current sensor, 2 non-contact micro-current sensors are respectively installed on signal output cables of the nitrogen pressure transmitter 1111 and the oil pressure transmitter 12 in a clamp manner, 4 non-contact micro-current sensors are respectively installed on power supply cables of a pump side main electromagnetic valve of the hydraulic control circuit 6, a pump side test electromagnetic valve of the hydraulic control circuit 6, a non-pump side main electromagnetic valve of the hydraulic control circuit 6 and a non-pump side test electromagnetic valve of the hydraulic control circuit 6 in a clamp manner, is used for measuring the output current of the nitrogen pressure transmitter 11 and the output current of the oil pressure transmitter 12, the output current of the nitrogen pressure transmitter 11 and the output current of the oil pressure transmitter 12 can be converted to obtain the actual values of the nitrogen pressure and the oil pressure, testing coil currents of the main electromagnetic valve and the test electromagnetic valve through the micro-current sensor 104, and obtaining action logics of the main electromagnetic valve and the test electromagnetic valve;

the current sensor 105 is a non-contact current sensor, and 3 non-contact current sensors are respectively installed on a three-phase power line of an oil pump motor of the hydraulic control loop 6 in a clamp type and used for testing the current of the oil pump motor of the valve;

the voltage sensor 106 is a three-phase voltage sensor, is installed at an input port of the oil pump motor power supply of the hydraulic control circuit 6, is in point-to-point corresponding conduction with the three-phase power supply, and is used for testing the voltage of the valve oil pump motor.

Step four: the control valve executes different working modes, and acquires parameters to be monitored selected in the first step through the sensor unit 1 in the process of executing different working modes (fast closing, slow closing, full opening and full opening), and the specific flow is as follows:

1. controlling the valve to execute opening action, and measuring various parameters to be monitored such as valve opening time, stroke, oil pressure, nitrogen pressure, seat separating force, reverse sealing force, friction force and the like in the opening action process of the valve;

2. controlling the valve to execute slow closing actions (slow closing at a pump side and slow closing at a non-pump side), and measuring parameters such as closing stroke, slow closing time, oil pressure and nitrogen pressure in the slow closing process, closing force of the valve in the slow closing process and the like in the action process;

3. controlling the valve to execute quick closing action (pump side quick closing, non-pump side quick closing), and measuring parameters of closing stroke, single side quick closing time, oil pressure and nitrogen pressure in the single side quick closing process, closing force of the valve in the single side quick closing process and the like in the action process;

4. the control valve executes quick closing action (pump side and non-pump side are quickly closed at the same time), and measures parameters such as closing stroke of the valve, single-side quick closing time, oil pressure and nitrogen pressure in the single-side quick closing process, closing force of the valve in the single-side quick closing process and the like in the action process.

Step five: and D, comparing and analyzing the measured value of each parameter to be monitored obtained in the fourth step with the allowable range of the theoretical value of each parameter to be detected determined in the second step, thereby obtaining a diagnosis conclusion. The specific process is as follows:

1. and (3) diagnosing the action performance: and diagnosing whether the action performance of the valve in executing each action meets the requirement. And comparing the measured values of parameters such as the action time and the like when the valve performs each action of opening, fast closing and slow closing with the theoretical value allowable range, and judging whether the overall action time when the valve performs each action meets the system operation requirement. If the action time is too long, the actually measured values of the parameters such as the nitrogen pressure, the oil pressure and the like need to be compared with the theoretical value allowable range, and whether the action time is too long due to the overlarge integral operation friction of the valve is judged by combining the nitrogen pressure and the oil pressure. If the whole friction force is normal, the aspects of abrasion of the valve core/valve seat, installation accuracy of the valve rod 8 and the like are checked; if the requirement is not met, the nitrogen pressure can be adjusted;

2. and (3) diagnosing the sealing performance: and diagnosing whether the sealing performance of the valve clack-valve seat, the valve rod 8-valve cover and other two sealing positions of the valve meets the requirements or not. Whether the sealing performance of the valve clack-valve seat contact part meets the requirement or not can be judged by comparing the measured values of the stroke, the closing force and the off-seat force and maintaining the allowable range of the theoretical value of normal operation; whether the sealing performance of the contact part of the valve rod 8 and the valve cover meets the requirement or not can be judged by comparing the measured value of the inverted sealing force with the theoretical value allowable range for maintaining normal operation; if the requirement is not met, the nitrogen pressure can be adjusted;

3. performance of an oil pump motor: and diagnosing whether the working current, voltage and power of the oil pump motor are normal or not, and whether the start-stop characteristic curve accords with the characteristics of the motor or not.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (6)

1. A nuclear power plant main steam isolation valve online diagnosis device is characterized by comprising a sensor unit, a signal detection unit, a data processing unit and an upper computer; the sensor unit, the signal detection unit, the data processing unit and the upper computer are in communication connection in sequence; the sensor unit is mechanically connected with a main steam isolation valve of a nuclear power plant.

2. The on-line diagnostic device for the main steam isolation valve of the nuclear power plant according to claim 1, wherein the sensor unit comprises a displacement sensor, a switching value sensor, a stress sensor, a micro-current sensor, a current sensor and a voltage sensor.

3. The nuclear power plant main steam isolating valve online diagnosis device according to claim 2, the moving part of the displacement sensor is arranged on the valve rod, the switching value sensor is connected with the normally open or normally closed contact of the limit switch, the stress sensor is fixedly arranged on the polished rod part of the valve rod, the micro-current sensor is respectively arranged on signal output cables of the nitrogen pressure transmitter and the oil pressure transmitter, a pump side main electromagnetic valve of the hydraulic control loop, a pump side test electromagnetic valve of the hydraulic control loop, a non-pump side main electromagnetic valve of the hydraulic control loop and a power supply cable of the non-pump side test electromagnetic valve of the hydraulic control loop, the current sensor is installed on a three-phase power line of an oil pump motor of the hydraulic control loop, and the voltage sensor is installed on a power input port of the oil pump motor in the hydraulic control loop and is in point-to-point corresponding conduction with the three-phase power.

4. The on-line diagnostic device for the main steam isolation valve of the nuclear power plant according to claim 2, wherein the displacement sensor is a pull-wire type displacement sensor, the switching value sensor is a multi-channel switching value sensor, the stress sensor is a patch type stress sensor, the micro current sensor is a non-contact micro current sensor, the current sensor is a non-contact current sensor, and the voltage sensor is a three-phase voltage sensor.

5. The nuclear power plant main steam isolating valve online diagnosis device according to claim 2, the signal detection unit comprises a displacement signal detection unit, a logic signal detection unit, a strain signal detection unit, a micro-current signal detection unit and a power detection unit, the current sensor and the voltage sensor are respectively in communication connection with the power detection unit, the switching value sensor is in communication connection with the logic signal detection unit, the displacement sensor is in communication connection with the displacement signal detection unit, the stress sensor is in communication connection with the strain signal detection unit, the micro-current sensor is in communication connection with the micro-current signal detection unit, and the displacement signal detection unit, the logic signal detection unit, the strain signal detection unit, the micro-current signal detection unit and the power detection unit are respectively connected with the data processing unit.

6. The on-line diagnosis device for the main steam isolation valve of the nuclear power plant according to claim 1, further comprising a power module and a management unit, wherein the power module and the management unit are respectively and mechanically connected with the sensor unit, the signal detection unit and the data processing unit, and the power module and the management unit are in communication connection with the data processing unit through serial ports.

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