CS212144B1 - Connected to signal transmission - Google Patents

Abstract

The invention relates to the automation of technological processes and solves the connection for transmitting signals from a telemechanization device to the computer memory. The received information comes to the decoder, where it is decoded using the time scale obtained from the time pulse generator, and the decoded information is written to the shift register. From its parallel outputs it is fed into the computer memory. The operation of all blocks of the connection is controlled and evaluated by the control circuit. The control circuit reports the results of checks and the operating status of the telemechanization device to the computer and offers it the received decoded information. The invention is used in automated control in the energy, transport, water and gas industries. The invention is defined in one point, the description is supplemented by one drawing.

Description

(54) Connected to signal transmission

The present invention relates to the automation of technological processes and to a circuit for transmitting signals from a telemechanization device to a computer memory. The received information arrives at the decoder, where it is decoded by the time scale obtained from the time pulse generator and the decoded information is written to the shift register. From its parallel outputs it is routed to the computer memory. The operation of all wiring blocks controls and evaluates the control circuit. The control circuit reports to the computer the results of the checks and the operating status of the telemechanization device and offers it the received decoded information.

The invention will be used in automated control in the energy, transport, water and gas industries.

The invention is defined in one point, the description being supplemented by one drawing.

The invention relates to a circuit for transmitting signals from a telemechanization device to a computer buffer, for remote control automation, control, measurement and signaling.

Connections for transmitting signals from a telemechanization device to a dispatching station and connections for transmitting signals to a computer are known. In both of these circuits, the serially received information is transmitted to a parallel information word. It was not necessary to check the correct operation of the telemechanization equipment for these connections. In the event of a telemechanization failure, the dispatcher immediately detected the failure. Also, when using a dedicated computer, the telemechanization error is immediately present. When using a powerful computer that processes several programs at the same time, it is necessary to check the correct operation of the telemechanization device.

It is necessary to check the formal correctness of the word of the received telemechanization device, that is its length, the operability of the transmission line, the operability of the serial reception register, the tuning of the operating frequencies of the transmitting and receiving station and timely reception of processed information by other circuits. At the same time, it is necessary to form a word for the computer about defects and operation of the telemechanization equipment and about the result of the above mentioned checks.

The object of the present invention is to provide a circuit for transmitting signals from a telemechanization device to a buffer according to the invention. It is based on the fact that the wiring data input is connected to the decoder data input and the control circuit data input. The clock input of the control circuit is connected to the second output of the clock pulse generator, the first output of which is connected to the clock input of the decoder. The first output of the decoder is connected to a shift output of the shift register, the serial input of which is connected to the second output of the decoder.

The third output of the decoder is connected to the zero input of the shift register, whose data group output is connected to the first group output of the wiring. The shift register control group output is coupled to the control circuit group control input whose first control output is coupled to the first wiring control output. The first wiring control input is coupled to the first control input of the control circuit whose group error output is coupled to the group wiring fault output. The second wiring control input is coupled to the second control input of the control circuit whose second control output is coupled to the second wiring control output. The group fault input of the wiring is connected to the group fault input of the control circuit.

An advantage of the arrangement according to the invention is that it allows to connect the computer directly behind the line receiver of the telemechanization device, so that the reception and processing of information for the computer is independent and technically substantially easier than when the information is read at the respective parallel outputs of the telemechanization device. This eliminates the need to convert up to 512 bits of the wide parallel word of the telemechanization device into a series of several words whose width is suitable for the selected computer. There is also no need to synchronize the operation of the computer with the telemechanization device.

Checking the length of the received word, checking the operability of the transmission link, and checking the operability of the serial reception register and checking the frequency tuning of the transmitting and receiving stations are greatly facilitated. The wiring is made up of a minimum number of commonly available and relatively inexpensive components and extends the modularity of the telemechanization equipment by the possibility of cooperation with a computer.

An example of a wiring according to the invention is shown in the block diagram of the attached drawing.

Individual wiring blocks can be characterized as follows:

The clock pulse generator J. consists of a synchronizable oscillator with a kmi212144 2-turn divider. It is a source of time pulses that are used to evaluate the time-coded received information.

The decoder 6 comprises a register and a combination circuit associated therewith. Used to decode the received information.

The shift register J is formed from memory elements, such as D-type flip-flops. Its width in bits corresponds to the word width of the computer used. Used to convert serially received decoded information into a parallel computer word.

The control circuit X is made up of sequential and combinational circuits to realize the logic functions that control and control the operation of all other wiring blocks. Individual blocks are connected as follows:

The wiring data input 51 is connected to the data input 21 of the decoder 2 and the data input 42 of the control circuit X. The clock input 41 of the control circuit X is coupled to the second output 12 of the clock pulse generator 1 whose first output 11 is connected to the clock input 22 of the decoder 2. The first output 23 of the decoder 2 is coupled to the shift output 33 of the shift register J whose serial input 34 is coupled to the second output 24 of the decoder 2. The third output 25 of the decoder á is coupled to the reset input 35 of the shift register J whose data group output. 31 is connected to the first wiring output group 61. Shift register control output 32 is coupled to group control input 44 of control circuit X whose first control output 48 is coupled to first wiring control output 62.

The first wiring control input 53 is coupled to the first control input 45 of the control circuit X, whose group error output 47 is coupled to the wiring group error output 63. The second wiring control input 54 is coupled to the second control input 46 of the control circuit X, whose second control output 49 is coupled to the second wiring control output 64. The group fault input 52 of the wiring is coupled to the group fault input 43 of the control circuit χ.

The circuitry for transmitting signals from the telemechanization device to the buffer operates as follows: The clock pulse generator X is continuously in operation and from its first output χχ, clock pulses are clocked at the clock input 22 of the decoder, whose frequency corresponds to the operating frequency of the telemechanization device. On the second output 12 of the clock pulse generator X there are pulses whose frequency is many times higher than the operating frequency of the telemechanization device. These pulses arrive at the clock input 41 of the control circuit X, where it serves as its synchronization pulses.

The received information comes from a line amplifier of a telemechanization device (not shown in the drawing) to the wiring data input 51 and from there to the data input 42 of the control circuit X, which ensures the correct function of the transmission path. At the same time, this information arrives at the data input 21 of the decoder 6, which decodes it by means of clock pulses arriving at its clock input 22. The decoded information bit by bit outputs through the second output 34 of the decoder 2, to the serial input 34 of the shift register J. Writing of individual bits to shift register J is performed by its shift input 33 by pulse coming from the first output 23 of decoder 2. in the transmission, it resets by a pulse on its reset input 35, which is supplied from the third output of the decoder 2, and arises as a decoded gap mark in the transmission.

Upon receipt of a specified number of bits corresponding to the word width of the computer, the received information via the data group output 31 of shift register J is converted to the first group output 61, where a computer is available. At the same time, the control symbol is converted to the group control input 44 of the control circuit χ via the group control output 32 of the shift register J. The control circuit X evaluates the check mark and offers the decoded information located at the first wiring output 61 to the computer via its first wiring output 46 to the wiring first output 62.

Upon receipt of the offered data, the computer acknowledges the control circuit 6 via the first control input 33 of the circuit to the first control input 45 of the control circuit. Simultaneously with the said data processing, the control circuit 5, via its group fault output 47, places the result of the checks and the state of the telemechanization device on the group fault output 63.

The status of the telemechanization device is sensed at the group fault input 52 of the wiring and applied to the group fault input 43 of the control circuit 6. The result of the checks performed and the result of the state of the telemechanization device are offered to the computer via the second output 49 of the control circuit 6 and from there through the second control output 64 of the wiring. The computer acknowledges receipt of the offered error message via the second control input 54 to the second control input 46 of the control circuit.

The invention will be used in the automation of technological process control in the energy, transport, water and gas industries.

Claims (1)

SUBJECT OF THE INVENTION A circuit for transmitting signals from a telemechanization device to a buffer, characterized in that the data input (51) is connected to the data input (21) of the decoder (2) and the data input (42) of the control circuit (4) whose clock input ( 41) is connected to the second output (12) of the clock pulse generator (1), the first output (11) of which is connected to the clock input (22) of the decoder (2), whose first output (23) of which is connected to the shift output (33) a shift register (3) whose serial input (34) is connected to a second output (24) of the decoder (2), the third output (25) of which is connected to a reset input (35) of the shift register (3) whose data group output ( 31) is coupled to the first wiring output group (61) and the control group output (32) of the shift register (3) is connected to the group control input (44) of the control circuit (4) whose first control output (48) is connected to the first control output (62) on A coupling whose first control input (53) is coupled to a first control input (45) of a control circuit (4), whose group error output (47) is coupled to a group fault output (63) of the wiring whose second control input (54) is connected to a second control input (46) of the control circuit (4), the second control output (49) of which is connected to the second control output (64) of the circuit, whose group error input (52) is connected to the group error input (43) of the control circuit (4).