SU563685A1 - Telemechanic system for disperced objects - Google Patents

Description

one

The invention relates to the field of information measuring equipment and telemechanics and is intended for the automated collection and transmission of information from objects of marine and other hard-to-reach oil and gas producing enterprises and the management of these objects.

In constructing the system, the following requirements were taken into account, due to the specific features of offshore oil producing enterprises:

cover objects rasiolol-shennye both on ramps and on individual bases (platforms) dispersed over a large area, with the functions of telecontrol (TU), tele-alarm (TC), telemetry of current values of parameters (TIT), telemetry of oil production wells (TID);

to ensure the reliable operation of the equipment in marine conditions of operation;

to ensure, in the absence of a centralized power supply for the bases, the long-term operation of the equipment of the controlled points (KP) from an autonomous source with limited power consumption.

Telemechanics systems are known that contain dispatch consoles at the control point, a code point transmission code block, an operation code transmission and reception block, an object number transmission code transmission block, a transmission resolution block, and a transceiver block, a transmission resolution block at controlled points, the unit receiving the code number of the controlled item, the unit receiving the operation code and actuators I.

These devices have very limited functionality both in terms of the amount of information transmitted and in the types of tele-ops performed and apnaratno complex.

The closest of the technical essence of the invention is the teleme.haniki system for dispersed objects, containing a dispatcher console at the control point, the first output of which is connected to the first inputs of the code block of the controlled point, the block of transmission and reception of the operation code, and the block and the code object numbers, the first inputs of which are connected to the first input of the transmission resolution block, the output of which is connected to the input of the transceiver unit, the processing and recording unit and the installation unit mode and work; at each controlled point, the outputs of the telemetry sensors are current)) x parameter values, status sensors

TV alarm and group metering objects are connected respectively to the first inputs of the current value measurement unit, the memory block of the state of the TV alarm objects, the drive unit and the program block for measuring the flow rate, the outputs of the receiving block of the code of the number of the controlled point and the block of receiving the operation code and connected to the first input of the block selection of telecontrol objects, the output connected to the actuating element, with the second inputs of the unit for measuring the current values of parameters, the block of accumulators and b The state of the object of remote signaling, the outputs of which, the storage unit and the measurement unit of the current parameter values are associated with the first input of the transmission resolution unit, the output of the receiving and transmitting unit connected to the input, the operating mode setting unit, the output of the power supply source connected to the third inputs of the unit the memory of the states of the tele-alarm objects and the storage unit and the second input of the program unit for measuring the flow rate, and the function switch 2.

However, this device has limited functionality, does not allow to cover objects located on separate sea bases, inefficiently uses the communication channel, is uneconomical from the point of view of energy consumption and is not reliable enough.

The purpose of the invention is to increase the information capacity, increase reliability, interference with performance and speed, reduce power consumption by equipment of controlled items, improve system usability, i.e., increase system efficiency.

This is achieved by the fact that a reception and transmission of service signals, an automatic exclusion of a monitored station, a reproducing unit of the state of tele-alarm objects, a measuring information receiving unit, an optimal reception unit, the first input of which is the first input of the receiving and transmitting service signals connected to the output of the transmitter and receiver unit. The output of the optimal reception unit is connected to the first inputs of the measuring information receiving unit, the reproducing unit of the state of TV alarm objects and the second inputs of the receiving and transmitting code of the object number and the receiving and transmitting code of the operation code, the second output of which is connected to the second inputs of the object reproducing unit remote signaling and measuring information receiving unit, output connected to the first input of the processing and recording unit. The output of the state-controlled object reproducing unit is combined with the first output of the dispatcher's console, the output of the mode setting unit is connected to the input of the automatic deletion of the monitored point, to the second inputs of the optimal reception unit, the reception and transmission unit of service signals, the transmission resolution unit, the number code transmission unit controlled point and the third input of the block of reception and transmission of the operation code. The first output of the overhead transmission signal receiving unit is connected to the first input of the transmission resolution block, one output of the monitored item elimination block and the second output of the reception and transmission signaling block is connected to the first input of the operation mode setting block. The second output of the automatic removal of the controlled point is connected to the third input of the transmission block of the code of the number of the controlled point. At each controlled point, an optimal reception unit, an automatic well exclusion unit, a service signal receiving and transmission unit, and a key element, one output of which is connected to the second input of the transceiver unit, are entered, to the first inputs of the code receiving block of the controlled point number, to the second input of the remote control object selection unit, to the first input of the automatic well exclusion unit and to the third input of the measurement unit of the current values of parameters. The output of the power source is connected to the input of the key element, the second output of which is connected to the second input of the transmission resolution unit and to the second inputs of the reception and transmission of service signals, the optimal reception unit, the receiving unit of the code of the controlled item number, the receiving unit of the operation code, the remote control object selection unit and an automatic well shutdown unit. The third output of the key element and the second output of the state storage unit of the signaling objects and the first output of the program unit for measuring the flow rate are connected to the third input of the storage unit and the second input of the transmission and reception unit of service signals, one output of which is connected to the second input of the operation mode setting unit, the other the output is connected to the first input of the transmission enable unit. The output of the transmitting / receiving unit is connected to the third input of the receiving and transmitting service signals unit and the optimal receiving unit, the output of which is connected to the third inputs of the receiving unit of the code of the controlled item number, the receiving unit of the operation code, the remote control object selection unit and the automatic exclusion of wells connected to the function switch and to the second input of the program block for measuring the flow rate, the second output connected to the fourth input of the block for the automatic elimination of wells.

A command prompt unit and an automatic coefficient input unit are entered at the control point, the output of which is connected to the second input of the processing and registration unit, the second output of the dispatcher console is connected to the first inputs of the command memory block and the automatic coefficient input unit, the output of the main memory block commands - to the first input of the transmission unit of the code of the number of the controlled point, the second outputs of which, the block of reception and transmission of the code of the object number and the third output of the reception and transmission unit of the operation code connected to the second inputs of the command memory unit and the automatic coefficient input unit. The control point contains a program block for measuring the flow rate, one output of which is connected to the first input of the transmission unit of the code of the number of the controlled point, the other to the second input of the processing and recording unit. The proposed system allows servicing offshore oilfield facilities located on ramps and individual bases. The latter are dispersed over a large area and, as already noted, are not provided with electricity. For servicing facilities located on these grounds, it is necessary to use an autonomous source of electricity with limited energy capacity to power the equipment of controlled points (KP). Thus, the equipment of a significant part of the controlled points connected to the system is critical to the power consumption. In the proposed system, the task of reducing the energy consumption of equipment KP is solved by rational construction of the structure of the system and the maximum simplification of the blocks that make up the equipment KP. The communication channel in the proposed system is a radio channel with one non-frequency for all control stations and the transmission of all types of information. The use of an obsh, its carrier frequency in the system, is caused by a sharp limitation, and sometimes by the possibility of receiving a division into two or more frequencies. FIG. 1 shows a block diagram of a control point and one of the controlled points (a circuit diagram using a power source with limited power consumption; a circuit diagram provided with electricity does not contain only a key element with a switching contact) of the proposed system; in fig. 2 is a block diagram of a command operational memory; in fig. 3- block for automatic input of TIT and TID coefficients. The system includes a controller 1 dispatcher, a command operative memory block 2, a program block for measuring the flow rate 4, a block 4 for automatic input of coefficients, a block 5 for processing and recording, a block 6 for transmitting the code of the number of the controlled point (CP), block 7 for receiving and transmitting operation code, block 8 of receiving and transmitting the object number code, block 9 of receiving and transmitting service signals, block 10 of setting the operating mode, block 11 of automatic deletion of the checkpoint, block 12 of reproducing the state of tele-alarm objects, block 13 of receiving measurement information, block approx 14 transmit permission, optimum reception block 15, plate-transmitting block 16, optal reception bt 17, block 18 for receiving and transmitting service signals, block 19 for setting the operating mode, block 20 for transmitting permission, block 21 for receiving the code of the number of the controlled point, operation code reception unit 22, remote control object selection unit 23, automatic well exclusion unit 24, production rate measuring program unit 25, storage unit 26, tele-alarm objects state memory unit 27, unit 28 measuring current parameter values, executive lementy 29 telecontrol function switch 30 (measuring unit group)} c schpova measuring unit 31, sensors 32 state objects telesignalization sensors 33 Telemetering current parameter values, the key member 34, a power source 35. The command operative memory unit 2 comprises a shift pulse element 36, a package size switching element 37, an address (number of packages) counter 38, a comparison element 39, an operation mode element 40, a command entry (input) element 41, a memory element 42, command issuing element 43, memory cell state analysis element 44. The b, 1 4 automatic coefficients input element includes a shift pulse generation element 45, a package size switching element 46, an address counter 47 (number of packages), a comparison element 48, a mode control element 49, a coefficient code recording element 50, a memory element 51 ti, element 52 of the coefficients. The main operation of the system is to carry out all the necessary telemechanical operations after a generalized signal is received from a control station for issuing information at the control point. In this mode, a system of priorities is established according to the types of information (TS, TID, TU, TIT) and the sequence of servicing of controlled POINTS (controlled sites using a source of energy with limited energy intensity, are serviced first). With the occurrence of information, t. C. when the state of the vehicle objects changes or when the well production information (TID) is ready, the key element 34 connects the gearbox equipment to the power source 35. Thereafter, in block 18 of receiving and transmitting overhead signals, a generic ready signal is generated. If within a certain time, the service signals are not received in the receiving and transmitting unit of service signals from the control point (PU), which notify

it is busy, then the mode setting unit 19 permits the transmission of a ready signal to the control center. The readiness signal, the passage through the transmission permission unit 20 and the transceiver unit 16, enters the reception and transmission service signaling unit 9, the input of which is connected to the input of the operation mode setting unit 10. At the same time, the mode setting unit allows the transmission of a signal for polling KP states generated in block 9 of receiving and transmitting service signals. This signal is transmitted to the control unit through transmission permission unit 14 and transceiver. unit 16 and is received by unit 18 for receiving and transmitting the signaling signals of all CPs. Thereafter, an output readiness signal is transmitted from the output of block 18 for receiving and transmitting service signals, via block 20 for transmitting permission, transmitting and transmitting block 16 to the control panel at a certain distributor clock, inherited by this control unit.

The address readiness signals of information from various control stations, passage through the transmitter-receiver unit 16 of the control unit, unit 9 of the reception and transmission of service signals, are received in unit 11 of the automatic removal of control equipment. At that, in block 6 of transmitting the code of the CP number, the code of the CP number, having its information, is automatically generated, and according to the permission signal from the operation mode setting unit 10, through the transmission permission unit 14, the transceiver unit 16 PU is fed to the control unit. The code of the CP number, received from the control panel through the transceiver receiving block 16 of the CP, the optimum reception block 17 is received by the block 21 of the reception of the code of the CP number code, the output of which is connected to the inputs of the drive block 26 and the object state memory 27. At the option of the control center, the transmission of information on the state of the vehicle objects or, in its absence, information on the production of wells is permitted. This information, consisting of the type of operation codes, the object meter and the control (at the vehicle) or measuring (at the ID) information, is transmitted to the control panel from the output of the vehicle state memory unit 27, the drive unit 26, through the peredari resolution unit 20, transceiver unit 16.

The address part of the information is transmitted through the CPM-CU unit 16 of the control unit, the optimal reception unit 15 to the reception and transmission units of operation code 7 and reception and transmission of the object code 8. If unit 8 is ir T, the operation code of the vehicle, the state code of the vehicle objects goes to the unit 12 reproducing the state of the objects of the vehicle. If unit 7 has received an operation code for measuring the flow rate of the TID, the measurement information on the flow rate of the wells is supplied to the measurement information receiving unit 13. After verifying the accuracy of this information is issued in the processing and registration unit 5.

At the end of the transmission of measurement information about the flow rate of the operating section, the operating mode setting unit 19 allows the automatic elimination block 24 to transfer the pneumatic functional switch 30 to the next operating well. Other operations on this control are carried out as follows.

After receiving information on the state of the vehicle objects and measuring information on well production from the control unit, the state of the command command memory 2 is interrogated. If in this block the operator in advance using the controller 1 of the dispatcher entered the codes of one or another operation (TU, control call of the state of objects of the vehicle and TIT, switch the well), provided for the gearbox, when it polls it issues a sigal, notifying conduct of a particular operation on this KP. The code of the necessary operation in the block 2 operational

the memory of commands is entered from block 7 by pressing the button “command input” on the remote controller. At that, the unit 2 is started, and the shift pulses from the element 36 enter the memory element 42 and the package size switching element 37, the output of which is connected to the input of the address counter 38. The latter sequentially generates codes of the CP and object number and outputs them to the comparison element 39, the other inputs of which receive the codes of the number of the desired CP and the object from blocks 6 and 8. When the counter 38 forms the address of the code of the CP number and the object, which coincides with the code of the CP number and an object coming from blocks 6 and 8, the comparison element 39 supplies

the correspondence signal, according to which the operation control element 40 generates a recording permission signal of the operation code from the output of block 7 through the command recording element to the memory element 42 and closes the flow of clock signals to the shift pulse generation element 45.

Upon completion of the recording, the element 44 of the analysis of the states of the memory cells generates a signal which enables the operation of the node 38 and prohibits

receipt of clock pulses in the element 36. Thus, the corresponding cells of the memory element 42 are entered with operation codes, which are necessary for those objects of a given CP, the numbers of which are received from the transmission unit of the object number transmission code. At the same time, the operating mode control element 40 issues a request signal to the operation mode setting unit 10 and, upon receiving the permission signal therefrom, sends a signal that sends the operation code from the memory element 42 through the command issuing element 43 to the operation code transmission and reception unit 7.

The operation codes and object numbers on the selected CP are transmitted by the enable signal from the operation mode setting unit 10, through the transmission enable unit 14, to the transceiver unit 16.

The information transmitted from the PU via the receiving-transmitting unit 16, the optimum receiving unit 17 enters the operation code receiving unit 22. If in block 22 an operation code TU is received, then the code of the object number is entered in unit 23 of the selection of objects TU, the output of which is connected to the actuating element 29 of the telecontrol. If in block 22, the operation code is to switch the well, then the code of the well number to be measured is entered in block 24 of the automatic elimination of the well, the output of which is connected to the input of the function switch 30. At receipt of the current values of sensor polling code in block 22 parameters, unit 28 for measuring current values of parameters sequentially polls sensors 33. According to the permission signal from unit 19 for setting the operation mode, this information from unit 28 for measuring current values of parameters, through unit 20 times Addressing information transmission, receiving and transmitting unit 16 is provided to the UE.

Information about the current values of the parameters, coming from the control unit through the transceiver unit 16 to the control unit, the optimum reception unit 15, is entered into the universal measuring information reception unit 13. After checking the accuracy of the received information, it is given to the processing and recording unit 5, where the corresponding coefficients from the automatic coefficient input unit 4, the operation of which is similar to the operation of the comapd unit 2, are received.

If block 22 receives the operation call code of the states of the objects of the vehicle, then block 27 is allowed to provide information on the state of the objects of the vehicle. This information on the permission signal from the operation mode setting unit 10 through the transmission permission unit 20, the transceiver unit 16 is supplied to the control panel. Information about the state of the objects of the vehicle, transmitted from the control unit, through the transceiver unit 16, the optimum reception unit 15 is written into the reproducing unit of the states of the objects of the vehicle.

After all the necessary operations are performed on the selected control unit by the permission signal from the mode setting unit 10, the service reception and transmission unit 9 generates a reset signal, which, passing through the transmission permission unit 14, the transceiver unit 16, is transmitted to the control signal. At the same time, the mode setting unit allows polling the next CD, from which the address information signal is received. The survey of this KP is similar to the previous one.

As already noted, the equipment of the controlled points provided by electric power does not contain the key element 34 and is permanently connected to the power source. Therefore, it is possible, upon release of the channel, to associate with this gearbox and to conduct the necessary telemechanical operations on them. Taking advantage of this opportunity, it is possible to simplify KP equipment, provided with electricity, by keeping a common program block 3 measuring the flow rate and, thereby, excluding the individual block 25 measuring a volume containing a significant amount of equipment on these KPs.

Controlled points provided with electricity, have a second priority in the order of servicing. Obtaining information about the state of the objects of the vehicle with these controls is also carried out as in the previous case. The survey results TID conducted by a predetermined program using the program unit 3 metering rate. If there is a requirement for conducting a TID operation from this block, the KP number code transmission block 6, the operation code transmission and reception block 7, and the object number transmission and reception block 8 are entered into the KP number, operation code and object number codes, respectively. According to the permission signal from the mode setting unit 10, these codes, via the transmission permission unit 14, the transceiver unit 16 are fed to the control panel. The information transmitted from the control center through the transmitting and receiving unit 16, the optimum receiving unit 17, respectively, goes to the receiving unit of the KP 21 code, receiving the operation code 22, and automatically excluding wells 24. Thereafter, the TID information accumulated in block 26 receives the permission signal from block 19 setting the operation mode through the transmission permission unit 20, the transceiver unit 16 is transmitted to the control panel.

The measurement information received from the control unit through the transceiver unit 16, the optimum reception unit 15 enters the measurement information receiving unit, which, in turn, after checking for accuracy, provides information to the processing and recording unit 5.

The other operations that have been described are carried out at any time both on request for these operations from the command command memory 2 and from the presence of requirements from the controller 1 controller, the output of which is also associated with the inputs of the code transmission block 6 KP number, block 7 of receiving and transmitting the operation code, block 8 of receiving and transmitting the code of the object number, block 10 of setting the operation mode. At the same time, the system operation algorithm is similar to the operation algorithm when performing the same operations at a gearbox, the equipment of which is powered from an autonomous power source with limited capacity.

Application in the system of new blocks at the control point: block 9 of receiving and transmitting service signals, block 15 of optimal reception, block of receiving measurement information, block 12 of reproducing the state of objects of the vehicle, block 11 of automatic deletion of gearboxes, block 2 of operating memory of commands, block 4 automatic input of TIT and TID coefficients, software

II

flow rate metering unit 3, and at controlled points: optimal reception unit 17, service signal receiving and transmitting unit 18, automatic well exclusion unit 24 favorably distinguishes the proposed system from the known ones, as the system capacity increases, the reliability and noise immunity of the transmission increases, the overall a radio channel of communication reduces the power consumption of equipment KP, which is especially important when servicing wells, operated with nomosh, separate grounds, which are not electrically connected Ossetia, increased reliability and performance, improved ease of use and simplified hardware manual.

Claims (3)

1. The telematics system for dispersed objects, containing a dispatcher console on the control point, the first output of which is connected to the first inputs of the code point transmission block, the operation code transmission and reception block, and the object number transmission and reception block, the first outputs of which are connected to the first the input of the transmission resolution block, the output of which is connected to the input of the transceiver unit, a processing and recording unit and a mode setting unit; At each monitored station, the outputs of telemeasurement sensors of the current values of parameters, sensors of the state of tele-alarm objects and group measuring installation are connected respectively to the first inputs of the measuring unit of current values of parameters, the memory block of states of tele-alarm objects, block of accumulators and program block for measuring the output, outputs the receiving unit of the code of the number of the controlled point and the receiving unit of the operation code are connected to the first input of the block for selecting the remote control objects, the output of which with an actuator, with the second inputs of the measurement unit of the current values of parameters, the storage unit and the memory block of the state of the tele-alarm objects, the outputs of which, the storage unit and the measurement unit of the current parameter values are connected to the first input of the transmission permission unit whose output is connected to the input / output the transmitting unit, the unit for setting the operation mode, the output of the power supply unit is connected to the third inputs of the memory unit of the state of the tele-alarm objects and the storage unit and the second input of the software The flow metering unit, and the function switch, characterized in that, in order to improve the efficiency of the system, a reception and transmission unit of service signals, a unit for automatically eliminating the monitored point, a unit for reproducing the state of tele-alarm objects, a unit for receiving measurement information are entered into the control point , block optimal at12 The first input of which and the first input of the block of reception and transmission of service signals are connected to the output of the receiving-transmitting unit, the output of the optimal reception unit is connected to the first inputs of the measuring information receiving unit, the reproducing unit of the state of tele-alarm objects and the second inputs of the receiving and transmitting code object and reception unit numbers and transmission of the operation code, the second output of which is connected to the second inputs of the reproducing unit of the states of the tele-alarm objects and the measuring information block, the output of which is connected to the first the input of the processing and recording unit, the output of the reproducing unit of the state of the remote signaling objects is combined with the first output of the dispatcher's console, the output of the operating mode setting unit is connected to the input block of automatic exclusion of the controlled point, to the second inputs of the optimal reception block, block of reception and transmission of service signals, block of transmission resolution, block of transfer of the code of the number of controlled point n to the third input of the block of reception and transmission of the operation code, first output of the block of reception and transmission of service signals connected with the first input of the transmission resolution block, one output of the monitored item elimination block and the second output of the block of reception and transmission of service signals are connected to the first input of the block and an operating mode, the second output unit controlled automatically eliminate the item connected to the third input of the code transmission unit controlled point numbers; at each controlled point an optimal reception unit, an automatic exclusion unit squall yn, a reception unit and transmission of service signals and a key element, one output of which is connected to the second input of the receiving-transmitting unit, to the first inputs of the receiving unit of the code of the number under control, the receiving unit of the code operations, to the second input of the telecontroller object selection unit, to the first input of the automatic well exclusion unit and to the third input of the current value measurement unit, the power supply output is connected to the key element input, the second output of which is connected to the second input of the transmission resolution block and to the second inputs block of reception and transmission of service signals, block optimal reception block receiving the code of the number of the controlled item, the block receiving the operation code, the block for selecting the remote control objects and the block for automatically eliminating wells, the third output of the key element and the second output of the state memory block of the tele-alarm objects and the first output of the program block for measuring the flow rate are connected to the third input of the storage block and the second the input of the block of transmission and reception of service signals, one output of which is connected to the second input of the setup unit of the Root mode, the other output is connected to the first input of the resolution block The output, the transceiver output, of its unit is connected to the third input of the reception and transmission of service signals and the optimal reception unit, the output of which is connected to the third inputs of the reception unit of the code of the controlled item number, the reception unit of the operation code, the unit for selecting remote control objects and the automatic deletion unit wells, the output of which is connected to the function switch and to the second input of the program block for measuring the flow rate, the second output of which is connected to the fourth input of the block for automatic elimination of well azhina. 2. The system according to claim 1, characterized in that at the control point, an operative command block and an automatic coefficient input unit are entered, the output of which is connected to the second input of the processing and recording unit, the second output of the dispatcher console is connected to the first inputs of the operational memory block these commands and the block for automatic input of coefficients, the output of the block of one-way memory of commands is connected to the first input of the transmission block of the code of the number of the controlled point whose second outputs, the block of reception and transmission of the code of the object number and three s output code reception and transmission unit connected to the second operation input unit operatpvnoy memory and automatic input block of coefficients. 3. The system for pi. 1 and 2, that is, at the control point a program block for measuring the flow rate is entered, one output of which is connected to the first input of the transmission unit of the code of the controlled point number, the other with the second input of the processing and recording unit. Sources of information taken into account in the examination 1. Author's certificate of the USSR Aig 2.26442, G 08С 19/28, 24.04.67. 2. Thematic scientific and technical review "Telemechanical complexes and devices for the automated process control system of the petroleum industry VNIINOENG," Telemechanics device for offshore oil fields. M., 1974, p. 11-35. -J-  U g  ; fj uj R fS / jOffffi fff-Z, 28 Ofnfj ofj