SU506897A1 - Device for transmitting and receiving telemechanical information - Google Patents

Description

one

This invention relates to telemetric systems and can be used in the oil industry.

Devices for transmitting and receiving telemechanical information are known, which contain a meter at monitored points, the input of which is connected to one of the outputs of the control unit, and the output to the first input of the accumulation unit, the outputs of which through the control unit are connected to the input of the information reception and transmission unit with the channel-forming units and the communication line, and at the control room — the control unit, whose input is connected to the time counting unit, and the output — to the trigger transmission unit, channel-type blocks Ovani, whose inputs are connected to the communication line.

The aim of the invention is to simplify the device and increase the reliability of its operation. This is achieved by introducing the stream number code generator and alarm generator at controlled points, the output of the stream number code generator is connected to the second input of the information receiving and transmitting unit, and the input is connected to the meter output, the output of the alarm generator is connected to the third input of the information receiving and transmitting unit, the second output of which is connected to the control unit, one of the outputs of which is connected to the pulse accumulation unit, and ki receiving signals shaper stream number, the address generator of the object and the alarm generator, wherein the outputs channeling units are connected to the first inputs iriema signal blocks, the first outputs of blocks

receiving signals are connected to the input of the address device of the object and the first input of the host module and information, and the second outputs of the signal receiving blocks are connected to the alarm driver, output

which is connected to the outputs of the object address formers and the stream number, the output of the time counting unit and the second input of the information representation unit, the third output of which is connected to the second output

the control unit, the first output of which is connected to the inputs of the time counting unit and the flow number generator, the second output of the flow number generator is connected to the second inputs of the signal receiving units.

The drawing shows a block diagram of the described device and the following notation is adopted: 1-meter; 2 - shaper code stream number; 3 - pulse accumulation unit; 4-control unit (KP);

5 - block reception and transmission (KP); 6 -

channelization unit; 7 -for worlds alarms; 8-control unit (DP); 9 - time counting unit; 10 is a block of transmission of start signals; And channeling unit; 12 - signal receiving unit;

13 - alarm generator;

14- address forcer of the object; 15 - flow number generator; 16 is a presentation unit.

The pre-meters 1 of all CPs are set to measure flows having the same conditional number, for example, the first. At the DP, the stream number 15 generator is also set to the "First" position. The next measurement begins with the generation of a series of 8 control signals at the PD. First, block 8 generates a reset signal to block 9 and shapers 14 and 13, then a control pulse to block 10, block 9 and shaper 15. Block 10 generates a trigger signal, coming through communication line 17 to all control stations.

Block 10 can generate two types of trigger signals: a start according to the Measurement program, which corresponds to a sufficiently long cycle of cost measurement to ensure the required accuracy, and a start according to the Control program, characterized by a short measurement cycle duration with low accuracy, the ultimate goal of which is to determine just the fact of the presence of the supply of wells. This or that program is selected either automatically by block 8, or forcibly set by the operator, or block OKO | M control 4 is selected on the gearbox.

Block 10, depending on the selected program, supplies the trigger signal with one of two qualitative features (for example, positive or negative polarity), which allow the program to determine the programmed signal of the program. The signal arriving at shaper 15, which is a multi-stable element (counter with decoder, niarovi finder, etc.), translates it into the next (second) state and issues to the blocks 12 a quality check sign of signals (for example, positive polarity), corresponding to the measurement of streams with conditional number “Second. At the same time, the time counting unit 9 is started. On all control stations, the start signal from communication line 17 is received by the beat unit depending on the selected program (Measurement or Control) control unit 4 is prepared to receive a signal about the end of accumulation C01M 3 by Hi3 of two outputs . At the same time, unit 3 is reset to the zero state, and unit 4 generates switching commands of meter 1 to flow measurement with conditional number "Second. After the switch is made, meter 1 generates and transmits a signal corresponding to stream no. 2 to driver 2, which in turn generates a sign

flow No. 2 and transmits it to block 5, where a control signal is generated to respond to a measurement start command, equipped with a corresponding qualitative indicator (for example, a positive polarity) corresponding to the flow number "Second. The control response signal is received through block 6 and communication line 17 to the corresponding block 11 and block 12 at the PD. TO

10 this moment on the DP, as mentioned above, all the blocks 12 receive the control qualitative sign of the signal from the driver 15. In case of a mismatch of the signs of the signal

5 The response and control at the output of the corresponding block 12 appears as an "Avariya" signal arriving at shaper 13 and causing the operation of the information representation unit 16. If the indicated symptoms match over all the 12 DP blocks, this indicates a synchronous start of flow measurement (wells) with number "second of all KP. In this case, the control unit 4 gives permission for filling the block with 3 pulses, producing: you are MI and; 3 | Measurer 1, in the process from Me | re1ni flow.

Unit 3 is a pulse accumulator and has two outputs: at the first output, the signal appears at full utilization of the research institute of storage capacitance (for example, 100 pulses), at the second, with partial filling (for example, 10 pulses). The full capacity of the drive is used when the program "Measurement, with the program" Control

5, only a portion of the storage capacity is used.

Depending on the selected program ("Measurement or" Control), the control unit 4 connects one of the outputs of block 3 to

3 to block 5. After accumulating a selected number of pulses by block 3 to block 5, it gives off a measurement end signal, which is supplied with the same quality sign as Y, the control response signal (for example, positive polarity); this signal on the DP, gets into the corresponding block 11, and then the block 12, triggers the information representation block 16, which records the time counted

Q from the beginning of the measurement of the flow number and the address of the object from which the measurement termination signal is received. In this case, to determine the daily flow rate (flow rate) of this flow, the ratio

a-f (() -H15

u - / izaa- / -, I deputy

where 1zy. var - the duration of the measurement time

(clock); 0C const - gauge constant;

jV const is the specified value of the number of pulses accumulated during measurement.

Therefore, with known C v. N p. Flow is determined by the time since the beginning

measurement before the arrival of the signal of the end of the measurement at this KP.

The time is counted on the DP by the block 9 and recorded at the time of arrival of the measurement end signal by the block 16. Since the flow rates of the measured flux at all CPs are generally different in magnitude, then the moments of arrival of the measurement termination signals from the CP are also different. At the same time, there is only a certain time limit Measurements, after which the measurements for all KPs must end. If by this time some KPs are not; stool signal of the end of measurement, this indicates that the flow rate according to KP is close to zero, i.e., the wells have no feed. After counting the time limit by block 9, a signal is sent to control unit 8, at which the measurement stops, and gearboxes from which no measurement end signals have come, are recorded by block 16 by the command of block 8 and the data of the imaging unit 14 as emergency ones.

In the event of an emergency situation at the control unit, the driver 7 issues an alarm signal to block 5. In block 5, this signal is supplied with a qualitative indication of an accident (for example, when measuring flow 2 - negative polarity), the block 6 passed, line 17, the corresponding blocks GT and 12 on DP, enters shaper 13 and is fixed by information representation block 16.

Claims (1)

Invention Formula A device for transmitting and receiving telemechanical information containing, at monitored points, a meter, the input of which is connected to one of the outputs of the control unit, and the output - to the first input of the accumulation unit, the outputs of which through the control unit are connected to the input of the information receiving and transmitting unit connected to a drip unit and a communication line, and at the control room — a control unit whose input is connected to a time counting unit, and an output — to a trigger signal transmission unit, channelization units, in the strokes of which are connected to the communication line, characterized in that, in order to simplify the device and increase the reliability of its operation, pego controlled points, the stream number code generator and the alarm generator, the output of the stream number code generator is connected to the second input of the information receiving and transmitting unit, and the input connected to the output of the meter, the output of the alarm generator is connected to the third input of the information receiving and transmitting unit, the second output of which is connected to the control unit, one of the outputs of which is connected to the pulse accumulating unit, and receiving units are entered at the control point, object address generator and alarm generator, and the outputs of the channelization units are connected to the first inputs of the signal receiving units, the first outputs of the signal receiving units are connected to the input of the object address generator and the first input of the presentation unit information, and the second outputs of the signal reception units are connected to the alarm driver, the output of which is connected to the outputs of the object address and stream number drivers, the output of the time counting unit and the second input of the information representation unit, the third output of which is connected to the second output of the control unit, the first output of which is connected to the inputs of the time counting unit and the stream number generator, the second output of the stream number generator is connected to the second inputs of the signal reception units.