RU2150756C1 - Method for gathering and processing signals in nuclear reactor core monitoring system, and device for its embodiment - Google Patents

Abstract

FIELD: nuclear power plants. SUBSTANCE: device has at least two parallel bus paths for passing signals from detector to two processors. All bus paths have identical hardware and software tools and are controlled using identical programs. Hardware tools include shared hardware (in particular, input device). These tools are controlled in each moment by only one of processors using its own bus path independently from other processors. When fault or error occurs in hardware of control path in shared channel part, control that uses it is switched off and other processors are informed about possibility to achieve control using other paths. EFFECT: independence of processors and paths, guaranteed validity of received parameters, when they are equal. 3 cl, 5 dwg

Description

 The invention relates to methods for transmitting data and systems for their implementation, and more specifically to methods and systems for collecting and processing signals in the system of in-line monitoring of the active zone of a nuclear reactor. When monitoring the active zones of reactor plants, the elements of control systems have high requirements for their reliability.

 One of the ways to increase the reliability of the system, important for safety, is to introduce redundancy of its components. The use of redundant components is possible at all stages of data collection and processing. Mandatory components of such systems are sensors located in the reactor core, data collection devices, including communication channels and processing tools for signals received from sensors.

 We introduce some definitions of the concepts that are used in this description.

 A sensor is a device that converts one or more parameters of a complex process into an analog electrical signal.

 A channel is a connection between devices through which information can be transferred from one device to another, providing the transmission of signals from the sensor installation area to a computing device that preprocesses data. A channel may consist of one or more parallel paths.

 A path is, in the general case, a multi-wire electrical connection that includes components such as amplifiers, signal converters, system lines.

 System trunks are communication lines and associated management tools. System trunks contain means for transmitting addresses, commands, and data. Examples of a system bus can be IEEE488, QBUS, MULTIBUS, etc., well-known in the field of computer technology.

 A partial redundant data transmission method using two parallel bus signal paths is described in US Pat. No. 4,490,785. This patent proposes a distributed computer network with nodes connected in pairs by channels from multiple paths (for example, two paths). Each path in each node has its own linear amplifier and receiver, and a single set of components (i.e., logical transmit and receive circuits) is used based on the separation between the two paths. Both paths are used interchangeably with assignment of functions on a random, equally probable basis. If an informational failure occurs or damage is detected on this path, the current path is switched from the bus interface. In the described solution, one bus path is operating at any given moment, and the other is in the “hot” reserve. Damage is easily detected, and not hidden, due to the alternate use of paths, which to some extent guarantees the detection of a channel malfunction. However, such a system requires two sensors, since one sensor, for example, a current one, cannot be connected to two parallel paths (for "hot" backup) - the signal value will significantly decrease, and the measurement accuracy will significantly decrease. In addition, this system works by using computer equipment at both ends of the bus to analyze transmitted messages.

 The disadvantages of such a system are the need for a double number of sensors and its complexity. The installation of expensive computer equipment on the part of the path that is located near the sensors in the reactor core would not be economically feasible.

 Another well-known way to increase the availability and reliability of a data transmission system is to transfer data in a partially duplicated manner described in US Pat. No. 4,974,144, where a peripheral device (sensor) is connected to an I / O controller using the first and second identical duplicate I / O paths. The interface receives synchronized synchronized signals, which are then transmitted to the central processing unit for processing. The disadvantage of such a transmission system is the difficulty in determining the place of occurrence of the malfunction and the moment of undesirable changes in the parameters of the system, from which it is necessary to take measures to restore its operability.

 In US patent N 4668465 (this patent is selected as a prototype), which describes a method and device for remote monitoring of processes in the volume of the active zone of a nuclear reactor, signals from sensors reflecting the position of the control rods are fed to the input devices of the measuring channel containing the transmitting part and two parallel bus paths connecting the sensors to the receiving part of the channel connected to two intermediate processors. The transmitting part of the channel contains input devices connected to the sensors. Each path contains means for generating a plurality of digital signals, means for storing said plurality of digital signals, and system lines having means for transmitting data, commands, and addresses. From one of the intermediate processors, the processed data is sent to the installation computer, which is a computing device of a higher level, and from the second, the processed data is fed to the display, where it is displayed in the form of histograms on a multi-page display. Both paths work simultaneously and independently, a discrepancy between the results is a signal for checking bus paths. The main advantage of this solution is the complete identity of the paths after the branching of the signal, their independence from each other, which ensures high reliability of the resulting process mappings.

 However, the intermediate processors operate according to different programs; there is no mechanism for changing the control of the operating mode of the input device in order, for example, to check sensors and paths or to change any parameters of the input device, for example, the gain.

 The intra-reactor monitoring system includes a combination of various intra-zone sensors, as well as a number of technological sensors, which ensure the monitoring of the state of the main technological equipment of the reactor installation (RU). The signals of various sensors have different effects on the reliability indicators for performing the functions of the system as a whole. So, for example, the reliability of obtaining a number of design parameters included in the so-called table of permissible values of RU parameters should be provided by redundancy of measurement functions. However, this redundancy may have the following limitations: 1) it is not always possible to connect two measuring channels to one sensor (as, for example, to the sensor mentioned above, which has a current signal at the output); 2) it is not always possible to install an "extra" sensor; 3) an increase in the number of input devices leads to a sharp increase in units of equipment.

 Thus, in order to reliably perform the hardware function of in-reactor monitoring, excessive redundancy of the paths for receiving, processing and transmitting signals from sensors is required and inevitably there is a need for a device for receiving a signal from the sensor for N paths (where N, for example, is equal to two). In addition, to ensure monitoring of the state (for example, serviceability) of sensors, confirmation of metrological characteristics, a systematic check of the state of the paths and sensors is necessary, associated with periodic changes in the parameters or operation mode of input devices, while one path must be independent of the second, as well as complete identity Used hardware and software in both ways. The need to check the state of the paths and change the parameters of the input devices require the transfer of control of the transmitting part of the channel from one path to another.

 The main technical problem solved by this invention is to provide a method and system for collecting and processing signals with a high degree of reliability and availability through the use of two (or more) parallel paths connecting the sensor to two (or more) identical computers. Another technical task when using two parallel paths is to resolve conflicts that arise when controlling an input device connected to a sensor from two computers working simultaneously on the same programs independently and independently.

 For a number of measuring channels of the reactor monitoring system, the need to control the operating mode or parameters of the input device is characteristic. As a rule, this is due to the need to change the transmission coefficient in the channel, monitoring the status of communication lines with the sensor, turning on / off the test modes of the input device, etc. Any change in the operating mode of the input device or a change in its parameters leads to a change in the signal value in the receiving part of both paths. The decision to perform any control function can be made by one processor, regardless of the operation of another processor. The state of the transmitting equipment should be able to find out in a different way by another processor that does not currently control the change in mode. The result of this may be a collision of influences on the common part of the channel from the side of the first and second processors. Another complication may be the appearance of a malfunction in the way in which the processor switched the operating mode of the input device, which can lead to the channel freezing in this state. The present invention allows to resolve conflicts arising in such situations.

The essence of the proposed method lies in the fact that when transmitting signals in the control system of the active zone of a nuclear reactor inside a closed structure through a measuring channel from a sensor to processors located outside this structure,
- generate an information signal inside the closed structure, representing the measurement value of the selected process parameter,
- convert the specified information signal into a set of redundant digital signals containing at least two redundant digital signals,
- remember the specified set of redundant digital signals,
- read the specified set of redundant digital signals on the specified measuring channel containing the transmitting part and at least two duplicate data transmission paths, the first of these paths - the first processor and the second of these paths - the second processor,
- generate in one of the processors from each redundant digital signal received through connected to the given processor one of the indicated data transmission paths, the first representation of the specified selected process parameter,
- the developed representation is transmitted to a computing device of a higher level,
- (followed by the distinguishing features of the proposed method),
- generate in the second processor at the same time and according to the programs identical to the first indicated processor from each redundant digital signal received through another of the indicated data transmission paths connected to the second processor, the second representation of the selected process parameter is identical to the first,
- the generated second presentation is passed to the specified computing device of a higher level, and
- when it becomes necessary to change the operating mode of the input device of the measuring channel along one of the backup paths, for example the first, the status word of the first path corresponding to the indicated changes is installed and stored in the transmitting part of the measuring channel,
- set the state of the changed mode in the transmitting part of the measuring channel,
- make the necessary changes in the mode of the transmitting part of the measuring channel,
- monitor the state of the operating mode of the transmitting part of the measuring channel on the first path by the first processor, and on the second path by the second processor,
- control in the transmitting part of the measuring channel the appearance of allowed and unresolved command words transmitted along the first path by the first processor,
- upon detection of unresolved command words transmitted by the first processor, or if the pause between adjacent allowed command words transmitted by the first processor is exceeded, the specified time interval in the transmitting part of the measuring channel is prohibited from controlling the change in the operating mode of the measuring channel along the first path and the first path failure flag is set,
- check the installation of the specified flag failure of the first path by the second processor on the second path,
- if it is necessary to additionally change the operating mode of the measuring channel that arose in the second processor and the first path failure flag is set, the status word of the second path corresponding to the indicated necessary changes is set and stored in the transmitting part of the measuring channel,
- set the device changes the operating mode of the input device of the measuring channel in the transmitting part of the measuring channel state of the changed mode,
- make the necessary changes in the operating mode of the measuring channel,
- monitor the state of the operating mode of the measuring channel on the first path by the first processor, and on the second path by the second processor,
- when a permitted command word is detected in the transmitting part of the measuring channel along the first path, the first path failure flag is cleared.

The essence of the system for implementing the above method is that it contains
- a sensor having at least one output,
- first and second processors,
- a computing device of a higher level connected to the specified first and second processors,
- moreover, the measuring channel has
- transmitting part and
- the first and second duplicating paths,
- moreover, the transmitting part contains an input device with at least one information input and output,
- and each path contains a means of generating multiple digital signals,
- a means of storing many digital signals and
- system trunk
- and each system line connects the transmitting part of the measuring channel with the corresponding processor,
- the specified sensor output is connected to the information input of the input device,
- the output of the input device is connected to the inputs of the means for generating multiple digital signals,
- the output of each means for generating multiple digital signals is connected to the input of the means for storing multiple digital signals of the corresponding path,
- the output of each means of storing a plurality of digital signals is connected to the corresponding system line,
(distinguishing features follow) the transmitting part of the measuring channel contains:
- a common for both paths means of changing the operating mode of the input device with at least two control inputs, two inhibit inputs and at least one output,
- common for both paths operating mode register with input and output,
- and each path contains a device for controlling the appearance of allowed and unresolved command words with input and output, and
- means for storing the status word of the corresponding path, containing a cell for fixing the failure state of this path,
moreover, the input device has at least one input change mode,
- the means for remembering the status word of the corresponding path has an input and output
- the cell for fixing the failure state of this path has an input and an output,
- the input of the control device is connected to the system trunk of the corresponding path,
- the output of the control device is connected to the corresponding input of the prohibition of means for changing the operating mode of the input device and the input of the cell to fix the failure state of this path,
- the output of each cell for fixing the failure state is connected to the system highways of both ways,
- input means for storing the word status of this path is connected to the corresponding system highway,
- the output of the means for storing the status word of this path is connected to the corresponding control input of the means of changing the operating mode of the input device,
- the output of the means for changing the operating mode is connected to the input of changing the operating mode of the input device and the input of the operating mode register, and
- the output of the operating mode register is connected to both system highways.

In another version, the system:
- the specified sensor has a second output,
- the specified input device has a second information input and a second input of changing the operating mode,
- the specified means of changing the operating mode of the input device has a second output,
- wherein said second sensor output is connected to said second information input of the input device, and said second input of changing the operating mode of the input device is connected to said second output of the means for changing the operating mode of the input device.

 The proposed method and system for its implementation are illustrated by the following figures.

 In FIG. Figure 1 shows a signal acquisition and processing system in a nuclear reactor core monitoring system, a sensor and a higher level computing device.

 In FIG. 2 shows the transmitting portion of the channel.

 In FIG. 3 shows a device for monitoring the occurrence of permitted and unresolved command words.

 In FIG. 4 shows a device for changing an operating mode of an input device.

 In FIG. 5 shows an input device.

List of designations:
1 - sensor;
2 - measuring channel;
3 - the first path of the measuring channel;
4 - the second path of the measuring channel;
5 - transmitting part of the measuring channel;
6 - the first processor;
7 - the second processor;
8 - computing device of a higher level;
9 - the boundary of the closed structure;
10 - information channel of communication of the first and second processors with a computing device of a higher level;
11 - system highway of the first path of the measuring channel;
12 - system highway of the second path of the measuring channel;
13 - the first input / output of the first processor;
14 - the first input / output of the second processor;
15 - second input / output of the first processor;
16 - second input / output of the second processor;
17 - input / output of a computing device of a higher level;
18 - means for generating multiple digital signals;
19 is a means of storing the specified set of digital signals;
20 - means for remembering the status word of the corresponding path;
21 - a device for controlling the appearance of permitted and unresolved command words;
22 - cell for fixing the state of failure of this path;
23 - input device;
24 - register operating mode;
25 - means for changing the operating mode of the input device;
26 - input control means changing the operating mode;
27 - input prohibition means of changing the operating mode;
28 - output means of changing the operating mode;
29 - input device control the appearance of permitted and unresolved command words;
30 - output device control the appearance of permitted and unresolved command words;
31 - the first information input of the input device;
32 - the second information input of the input device;
33 - output of the input device;
34 - the first output of the sensor;
35 - the second output of the sensor;
36 - address recognition device;
37 - command recognition device;
38 - timer;
39 - output signal "the appearance of the right team";
40 - input reset timer;
41 - timer output:
42 - means of fixing the appearance of an incorrect command;
43 - the first input of the installation of the fixing means;
44 - output signal "the appearance of an incorrect command";
45 - input reset means of fixation;
46 - the second input of the installation of the fixing means;
47 - the first circuit that implements the logical function "AND";
48 is a second diagram that implements the logical function "AND";
49 - the third circuit that implements the logical function "AND";
50 - the fourth scheme that implements the logical function "AND";
51 - gain control device input device;
52 - device for controlling the type of sensor connection;
53 - the first input of the circuit that implements the logical function "AND";
54 - the second input of the circuit that implements the logical function "AND";
55 - output changes the gain of the input device;
56 - output changes the type of connection of the sensor;
57 - the first operational amplifier;
58 - the second operational amplifier;
59 - the third operational amplifier;
60 - the first contact of the device controlling the type of connection of the sensor;
61 is a second contact device control type of connection of the sensor;
62 - the third contact of the control device type of connection of the sensor;
63 - site adjustable feedback;
64 - the first input of an operational amplifier;
65 - the second input of the operational amplifier;
66 - input gain control input device;
67 - input control type of connection of the sensor;
R1, R2, R3 - ohmic resistance (transient, feedback and bias).

 In FIG. 1 shows a sensor 1, channel 2 of a signal acquisition and processing system, and a higher-level computing device 8. As sensor 1, for example, a β-emission detector, an ionization chamber, a resistance thermometer, or a thermocouple can be used. Channel 2 contains the transmitting part 5 and the first 3 and second 4 duplicate paths. The first path 3 contains a system highway 11 containing means for transmitting commands, addresses, and data (the latter are not shown in FIG.). The second path 4 contains a system bus 12 containing means for transmitting commands, addresses and data (the latter are not shown in FIG.).

 The system highway 11 of the first path 3 is connected to the first input / output 13 of the first processor 6, the system highway 12 of the second path 4 is connected to the first input / output 14 of the second processor 7. The second inputs / outputs 15 and 16 of the processors 6 and 7 are connected to the input / output 17 of the computing device of a higher level 8 by an information communication channel 10. Sensor 1 is located inside a closed structure in the volume of the reactor core. It has at least three leads, one of which is connected to the ground, and two other leads are wired to the transmitting part 5 of channel 2, which is separated from the sensor 1 by the boundary 9 of the closed structure.

 In FIG. 2 shows in more detail the transmitting part 5 of channel 2. Two outputs (34 and 35) of the sensor 1 are connected to the information inputs 31 and 32 of the input device 23, the output of which 33 is connected to the inputs of the means for generating a plurality of digital signals 18, which can be, for example, analog -digital converters (ADC), the first 3 and second 4 paths of channel 2. The outputs of the ADC 18 of each path are connected to the inputs of the means for storing a variety of digital signals 19, which can be made in the form of registers (and hereinafter will be called data registers), the outputs of the cat ryh connected with means for data transmission (Fig. not shown) of system lines (11 or 12) of the respective paths. In addition, for each path there is a tool 20 for storing the status word of the corresponding path, the tool 20 can be made in the form of a register (and hereinafter will be called a status register), the input of which is connected to a means for transmitting data (not shown in Fig.) System highway (11 or 12) of the corresponding path, and the output to the corresponding input 26 of the control means of changing the operating mode 25 of the input device 23. For each path there is a device for monitoring the appearance of allowed and unresolved command words 21, the input of which 29 is connected to the means for transmitting commands and addresses (not shown in Fig.) of the system highways (11 or 12) of the corresponding path, and the output 30 is connected to the corresponding input 27 of the prohibition means 25 for changing the operating mode of the input device and the input of the cell 22 for fixing The failure state of this path. (This cell can be made in the form of a trigger and hereinafter it will be called a failure trigger). The output of the fault trigger 22 is connected to the means for transmitting data (not shown in Fig.) Of the system lines 11 and 12 of both paths 3 and 4. It should be noted that the fault trigger 22 of this path can be performed as part of the state register 20, or as a separate trigger.

 In FIG. 3 shows an embodiment of a device 21 for monitoring the occurrence of allowed and unresolved command words. The input 29 of the device 21 for controlling the occurrence of allowed and unresolved command words is connected to the means for transmitting addresses and means for transmitting commands (not shown in FIG.) To the system highway 11 (or 12) of the corresponding path. The input of the address recognition device 36 is connected to the indicated means for transmitting addresses (not shown in FIG.). The first input of the command recognition device 37 is connected to the indicated means for transmitting commands (not shown in FIG.) To the system line 11 (or 12) of the corresponding path. The output of the address recognition device 36 is connected to the second input of the command recognition device 37. The output 44 of the “correct command appearance” signal of the command recognition device 37 is connected to the reset input 40 of the timer 38. In addition, the output 44 is connected to the reset input 45 of the incorrect command fixation tool 42 . The output 39 of the signal "appearance of the correct command" of the command recognition device 37 is connected to the second input 46 of the installation of the fixing means 42. The output 30 of the means of fixing the occurrence of the wrong command 42 is the output of the device 21 for controlling the occurrence of allowed and unresolved command words.

 In FIG. 4 shows an embodiment of a means 25 for changing an operating mode of an input device. The control inputs 26 and the inputs of the prohibition 27 means changing the operating mode of the input device are divided into two groups. The first one (for example, consisting of the inputs at the top of FIG. 4) refers to path 3, and the second (for example, consisting of the inputs at the bottom of FIG. 4) refers to path 4. The groups are identical. The control input 26 of the first group is connected to the first inputs 53 of circuits that implement the logical function "AND" (hereinafter simply the "AND" circuits) 47 and 48, the control input 26 of the second group is connected to the first inputs of 53 circuits that implement the logical function "AND" (hereinafter just "I" circuits) 49 and 50. The number of "I" circuits belonging to this group is determined by the number of options for changing the operating mode of the input device (there are 2 of them in the considered option, but there can be more). To the second inputs of the circuits "And" 47 and 48 related to this group, the control input 27 of the means for changing the operating mode is connected. Similarly, in the second group, the control input 27 of the means for changing the operating mode of the second group is connected to the second inputs of the AND circuits 49 and 50. The outputs of the And circuits of both groups are connected to the inputs of the circuits 51 and 52 so that the outputs of the And circuits 47 and 49 are connected to the inputs of the circuit 51, and the outputs of the And circuits 48 and 50 are connected to the inputs of the circuit 52. The circuit 51 is gain control device of the input device, circuit 52 is a device for controlling the type of sensor connection. The number of control device circuits (in this example, circuits 51, 52) is also equal to the number of options for changing the operating mode of the input device 23. Outputs 55 and 56 (circuits 51 and 52, respectively) form the output 28 of the means for changing the operating mode 25.

 In FIG. 5 shows a variant of the input device 23 (when using a β-emission detector as a sensor). Information inputs 31 (for example, from the output of the sensor emitter) and 32 (for example, from the output of the sensor background) are connected to the first inputs 64 of the first and second operational amplifiers 57 and 58. The second inputs 65 of the operational amplifiers 57 and 58 are connected to ground. Contacts 60,61 and 62 belong to the device 52 for controlling the type of connection of the sensor and are controlled by it. They are shown conditionally, because these are actually the contacts of electronic switches. The outputs of the operational amplifiers 57 and 58 are connected (via resistances R1) to the inputs 64 and 65 of the third operational amplifier 59, respectively. In addition, the output of the operational amplifier 57 through the feedback resistance R2 is connected to its input 64 and through the specified contact 61 to the output 33 of the input devices 23. Similarly, the output of the operational amplifier 58 through the feedback resistance R2 is connected to its input 64, and through the specified contact 62 to the output 33 of the input device 23. The input 65 of the operational amplifier 59 through the resistance R3 is connected to emley. The output of the operational amplifier 59 through the terminal 60 of the sensor connection type control device 52 is connected to the output 33 of the input device 23. In addition, the output of the operational amplifier 59 is connected to its input 64 through the adjustable feedback node 63. The input of the gain control 66 of the input device is connected to the node 63 adjustable feedback, and is also connected to the output 55 of the gain change of the input device. The control input of the type of connection of the sensor 67 is connected to the output 56 of the change in the type of connection of the sensor.

The operation of the signal collection and processing system
When the system is operating in the main measuring mode, the analog signals from sensor 1 (Fig. 1), corresponding to the values of the selected operating parameter of the nuclear reactor, go to the transmitting part 5 of channel 2, where two redundant digital signals are generated, which are on the main lines 11 and 12 of the first 3 and the second 4 paths go to the first 6 and second 7 processors. Here they are processed using completely identical programs and the results of their processing via the information communication channel 10 are supplied to a higher-level computing device 8. The analog signals from the outputs 34 and 35 of the sensor 1 (Fig. 2) are fed to the information inputs 31 and 32 of the input device 23, from the output 33 of which they fall on two analog-to-digital converters 18 of the corresponding paths 3 and 4, where they are converted into redundant redundant each other's digital signals. These signals fall into the data registers 19 of the corresponding paths. From the outputs of the data registers 19 on the system line 11 (or 12), these data are read by the corresponding processor. On the same system highways, both processors control means 25 for changing the operating mode. For this, in each of the paths 3 and 4 there is a status register 20, which remembers the status word transmitted along the corresponding highway 11 (or 12) connected to it by the processor 6 (or 7). This status word is supplied to the control input 27 of the means 25 changing the operating mode. The input 29 of the device 21 controlling the appearance of allowed and unresolved command words from the corresponding line 11 or 12 receives command words and addresses from the processor. When an unauthorized command arrives at the address assigned to this sensor 1 or the arrival of the next allowed command is delayed for more than a specified period, the signal from the output 30 of the control device 21 of the occurrence of allowed and unauthorized command words is sent to the inhibition input 26 of the means 25 for changing the operating mode of the input device, prohibiting the effect of the status word at the control input 27 on the means 25 of changing the operating mode of the input device. The signal from the output 30 of the control device 21 also enters the input of the trigger of the failure 22 of this path and sets it to unity. The output of the fault trigger 22 is connected to both system highways 11 and 12, therefore its state is available for interrogation to both processors 6 and 7.

 If one of the processors 6 and 7, for example the first 6, needed to change the operating mode of the input device 23, a new status word is transmitted to the status register 20 along the system line 11 of the first path. If the control device 21 of this path does not give a signal to the inhibit input 26, received at the control input 27 of the means 25 for changing the operating mode of the input device, the status word will make the corresponding changes and the necessary control signals for the input device 23 will appear at the output of the means 25. In addition, the signals from the output 28 they go to the operating mode register 24, from which information can be read by both processors along the lines 11 and 12. The second processor 7, therefore, has information about When the reset trigger 22 of the first path 3 and the signals controlling the input device 23 are determined by the status word transmitted by the first processor 6. If the control device 21 of the first path 3 generates an unresolved command word (or a delay of the arrival of the allowed command word), the trigger is set to unity failure 22 and the passage of the control signal of the means 25 changing the operating mode of the input device from the state register 20 of the first path 3 through the input 27 is prohibited. If the second processor 7 has a need and changing the parameters of the input device 23, then when the first trigger path 22 failure is set to one, the second processor 7 sets the status word on the highway 12 to the corresponding status register 20 of the second path 4. Now the input device 23 is controlled by means 25 of changing the operating mode of the input device under the influence of signals at the input 27 from the state register 20 of the second path 4.

 The first processor 6 will again be able to take control of the input device 23 if such a need arises in it, only if, for any reason, the failure trigger 22 of the second path 4 is set to unity.

 One of the reasons for the control device 21 to operate and the failure trigger 22 to be set to one may be damage to the line 11 or 12, which leads to a delay in the appearance of the next allowed command for a time longer than a predetermined interval. Such a “freeze” is especially unacceptable if, before that, the processor controlling the input device 23 mode switched the input device 23 into a test mode, in which signals that do not correspond to the value of the observed process parameter are transmitted from the sensor 1 on both paths 3 and 4 of channel 2. In this case, setting the failure trigger 21 allows another processor to take control and switch the input device 23 to the main monitoring mode.

 The control device 21 (Fig. 3) works as follows. When the address assigned to this sensor 1 arrives at the address recognition device 36 at the input 29 from the system trunk (11 or 12) of this path, the address recognition device 36 allows the command recognition device 37 to receive and analyze the control word. If this is a permitted command word, the device 37 at the output 44 supplies a signal to the input 40 of resetting the timer 38, which starts counting clock cycles to determine the amount of time between adjacent allowed commands. If the command word was unresolved, a signal is output from output 39 of device 37 to input 46 of circuit 42, which sets it to “1”. In another case, if the next allowed command is delayed, there is no signal from output 44 to the input 40 of resetting the timer 38. Then, after a specified number of clock cycles, the output 41 of the timer 38 will receive a signal that, when entering the input 43 of the circuit 42, also sets it to "1 " When the circuit 42 is set to "1", a signal appears on its output 30, which is a prohibition signal at the input 26 of the device 25 (in Fig. 2). The signal at the output 30 sets in "1" cell 22 to fix the failure state of this path (in Fig. 2). The above-mentioned signal at the output 44 of the device 37 (appearing upon the arrival of the allowed control word) is also input to the circuit 45 of the circuit 42 and resets it to "0". In this case, the inhibit signal at the output 30 disappears. Thus, the arrival of the next recognized authorized command causes a reset to “0” of the means for fixing the occurrence of an incorrect command (circuit 42) and then a reset to “0” of cell 22, which removes the indication of the failure state of this path (in Fig. 2).

 Means 25 changing the operating mode of the input device (Fig. 4) works as follows. The tool 25 has, as can be seen from the diagram, two symmetrical parts related respectively to the first 3 and second 4 channel paths. Consider the work of one of them, the second acts similarly. The control input 26 from the state register 20 (Fig. 2) receives signals of a change in the operating mode of the input device 23. In this embodiment, one of the two possible signals arrives at the input 26 at the same time, but this is a simplified option for illustration, other similar control methods are possible using combinations of signals on input wires 26. The signal values are determined by the status word in the status register 20 (Fig. 2). The signal from input 26 passes the corresponding circuit "And" (for example, 47) and is fed to the input of circuit 51 (gain control device of the input device). To the second input of the And circuit 47 from input 27, a prohibition signal for changing the mode of operation is received, which prohibits the passage of the signal from input 26 (or allows the passage of this signal if a malfunction does not occur, detected by the device 20 for monitoring the appearance of allowed and unresolved command words) . The signal from the output 55 of the circuit 51 provides a change in the gain of the input device 23 by changing the resistance of the adjustable feedback unit 63 of the operational amplifier 59 (Fig. 5). Another control signal from AND circuits 48 or 50 may be input to circuit 52 (control device for the type of sensor connection). The device 52 with its signals at the output 56 provides a change in the type of connection of the sensor 1, as will be described below.

 The input device (Fig. 5) works as follows. In the main mode of monitoring the operation of the reactor at the input 64 of the operational amplifier 57 from the sensor 1 (for example, β-emission detector) through the input 31 receives a current signal of the emitter of the sensor. At the same time, input 64 of the operational amplifier 58 from the sensor 1 through the input 32 receives the signal current of the background sensor. The second inputs of 65 operational amplifiers 57 and 58 are fed ground potential. The amplified signals from the outputs of the operational amplifiers 57 and 58 are fed to the inputs 64 and 65 of the operational amplifier 59, the amplified difference of these signals from the output of the operational amplifier 59 through a closed contact 60 is supplied to the output 33 of the input device 23. Contacts 62 and 63 are open in this mode.

 If it is necessary to change the gain of the input device, the circuit 51 (Fig. 4) produces at the input 66 a change in the resistance of the variable feedback unit 63 of the operational amplifier 59.

 If it is necessary to measure the insulation resistance of the circuit of the emitter of the sensor 1, a signal is supplied to input 67 from circuit 52 (Fig. 4), which closes contact 61, while contacts 60 and 62 are open. Thus, the first output 34 of the sensor 1, connected to the emitter of the sensor, through the first information input 31 is connected to the output 33 of the input device. The received signal after being digitalized in the means 18 (Fig. 2) for generating a plurality of digital signals is supplied to the means 19 for storing the indicated plurality of digital signals, from where it can be read along the line 11 or 12 by the corresponding processor 6 or 7. If it is necessary to measure the insulation resistance of the circuit sensor background, the input 67 from the circuit 52 (Fig. 4) receives a signal that closes the contact 62, while the contacts 60 and 61 are open. The second output 35 of the sensor 1, connected to the background circuit of the sensor, through the second information input 32 is connected to the output 33 of the input device. The received signal, after being digitalized in the means 18 (Fig. 2) for generating a plurality of digital signals, is supplied to the means 19 for storing the indicated plurality of digital signals, from where it can also be read on the highway 11 or 12 by the corresponding processor 6 or 7. Thus, it is possible to separately measure the insulation resistance of the emitter circuit and the background circuit of the sensor.

 The proposed method for collecting and processing data and a system for its implementation provide conflict-free control of the change in the sensor signals from several (for example, two) redundant processors that operate according to the same programs independently and are connected to the sensor by a channel containing the same independent paths. The independence of paths and processors guarantees the reliability of the obtained parameters when their values coincide. The proposed method allows you to have a relatively simple and reliable equipment for resolving control conflicts on the transmitting part of the channel.

 From the point of view of industrial feasibility of the proposed system, it should be noted that it can be manufactured using widely used inexpensive components, which is especially important when using a large number of sensors in the area of a nuclear reactor for monitoring.

Claims (3)

 1. The method of collecting and processing signals in the control system of the active zone of a nuclear reactor inside a closed structure through a measuring channel from a sensor to processors located outside this structure, which means that they generate an information signal inside the closed structure that represents the measurement value of the selected process parameter, convert the specified information signal into a set of redundant digital signals containing at least two redundant digital signals, remember the specified sets about redundant digital signals, read the specified set of redundant digital signals on the specified measuring channel containing the transmitting part and at least two duplicate data transmission paths, on the first of these paths by the first processor and on the second of these paths by the second processor, in one of the processors from each redundant digital signal received via one of the indicated data transmission paths connected to the given processor, the first representation of the selected about the process parameter, the developed representation is transmitted to a higher-level computing device, characterized in that it is generated in the second processor at the same time and according to the programs identical to the first indicated by the processor from each redundant digital signal received through another of the indicated data transmission paths connected to the second processor, the second representation of the specified selected process parameter, identical to the first, the generated second representation is transmitted to the specified computing device about a higher level, and when it becomes necessary to change the operating mode of the input device of the measuring channel along one of the backup paths, for example, the first, the status word of the first path corresponding to the indicated changes is established and stored in the transmitting part of the measuring channel, the state is set in the transmitting part of the measuring channel altered mode, make the necessary changes in the mode of the transmitting part of the measuring channel, monitor the state of the operating mode of the transmitting part from On the first path, the first processor, and on the second path, the second processor, in the transmitting part of the measuring channel, the occurrence of allowed and unresolved command words transmitted along the first path by the first processor is monitored if unresolved command words transmitted by the first processor are detected, or if a pause between adjacent allowed command words transmitted by the first processor, the specified time interval in the transmitting part of the measuring channel prohibit control by measuring the operating mode of the measuring channel along the first path and setting the first path failure flag, check the installation of the specified first path failure flag by the second processor on the second path, if necessary, additionally changing the measuring channel operating mode that occurred in the second processor and the first path failure flag is set and remember in the transmitting part of the measuring channel the status word of the second path corresponding to the specified necessary changes, set in the device the operating mode of the input device of the measuring channel in the transmitting part of the measuring channel changes the state of the changed mode, make the necessary changes to the operating mode of the measuring channel, control the state of the operating mode of the measuring channel on the first path by the first processor, and on the second path by the second processor, if it is detected in the transmitting part of the measuring channel allowed command word on the first path, clear the first path failure flag.  2. A system for transmitting a plurality of signals representing values of a selected process parameter flowing in the reactor core within a closed structure through a measuring channel from a sensor to processors located outside this structure, comprising a sensor having at least one output, the first and a second processor, a higher level computing device connected to said first and second processors, the measurement channel having a transmitting part and first and second duplicating n uti, moreover, the transmitting part comprises an input device with at least one information input and output, and each path contains means for generating a plurality of digital signals, means for storing a plurality of digital signals and a system bus, each system bus connecting a transmitting part of the measuring channel to the corresponding the processor, the specified output of the sensor is connected to the information input of the input device, the output of the input device is connected to the inputs of the generation of multiple digital ignals, the output of each means for generating a plurality of digital signals is connected to the input of the means for storing a plurality of digital signals of a corresponding path, the output of each means for storing a plurality of digital signals is connected to a corresponding system highway, characterized in that the transmitting part of the measuring channel contains means for changing the operating mode common to both ways an input device with at least two control inputs, two inhibit inputs, and at least one output common to both We have a register of the operating mode with input and output, and each path contains a device for monitoring the appearance of allowed and unresolved command words with input and output and a means for storing the status word of the corresponding path, containing a cell for fixing the failure state of this path, and the input device has at least at least one input for changing the operating mode, the means for storing the status word of the corresponding path has an input and output, the cell for fixing the failure state of this path has an input and output, the input of the device The path is connected to the system trunk of the corresponding path, the output of the monitoring device is connected to the corresponding inhibition of the means for changing the operating mode of the input device and the input of the cell to fix the failure status of this path, the output of each cell to fix the failure status is connected to the system trunks of both paths, the input of the means for storing the status word of the given path is connected to the corresponding system highway, the output of the means for storing the status word of this path is connected to the corresponding Odom control means changes the operating mode of the input device, the output means changes the mode of operation coupled to an input mode change operation input device and the input of the operation mode register, a mode register output operation is connected with both systemic routes.  3. The transmission system according to claim 2, characterized in that said sensor has a second output, said input device has a second information input and a second change mode input, said means of changing an input device mode of operation has a second output, said second sensor output being connected with the specified second information input of the input device, and the specified second input of the change in the operating mode of the input device is connected to the specified second output of the means for changing the operating mode of the input device.

Images