RU1766190C - Device for control of process variable - Google Patents

Abstract

FIELD: automation. SUBSTANCE: device has two amplitude control levels. On the first level the operation of threshold element 4 is controlled by two-threshold comparator 7. In case of coincidence of operating levels of element 4 and of the allowance set by comparator 7, D-flip-flop 9 authorizes allowance control on the second level of the controlled variable. EFFECT: higher reliability of control. 1 dwg

Description

 The invention relates to automation and can be used to control vibration parameters of a gas turbine engine.

 Known devices for controlling the limiting vibration parameters of the housing of a gas turbine engine, comprising a sensor, an electronic conversion unit and an actuating element.

 However, such signaling devices do not exclude the possibility of issuing inaccurate information about the current value of the controlled technological parameter (vibration) and about exceeding the maximum permissible level of this parameter in case of electronic element radioelements failures.

 A device is known for monitoring technological parameters, namely vibration parameters, with a self-monitoring system that reduces the likelihood of false information, comprising a sensor, an adder, a measuring transducer and a threshold element connected in series, as well as a control signal generator and a key.

 The self-control system is formed in series by a control signal generator and a key, the output of which is connected to the second input of the adder. When the key is closed, a control signal from the generator is supplied to the second input of the adder and the operator evaluates the correct functioning of the device by analyzing the state of its output signals. Periodic testing of the device with the help of a self-monitoring system makes it possible to identify such malfunctions as, for example, breaks and short circuits of electrical targets, failures of radio elements of an electronic circuit.

 However, the test result is evaluated by the operator only qualitatively, with a large error, which is a significant disadvantage of the prototype, since the signaling device malfunctions are not detected at an early stage of a defect (for example, when radioelements age).

 The accuracy of monitoring the transmittance of the measuring transducer in this case is determined mainly by the accuracy class of the external indicator and, as a rule, does not meet the requirements for the electronic part of the device.

 The threshold element is monitored on a discrete basis (it worked or did not work), and the signal level at which it was triggered is not determined. In addition, subjective errors of the operator during verification are not ruled out, since the assessment of its result is not automated.

 The aim of the invention is to increase the reliability of the control of the technological parameter by increasing the fineness of diagnosing the technical condition of the device in operation without removing it from the object.

 The use of the invention will allow to identify device malfunctions at an early stage of their occurrence without the use of additional control tools (test equipment, standard test equipment), significantly reduce the amount of scheduled maintenance work on checking the device and, accordingly, the cost of its maintenance.

 To achieve this goal, the proposed device containing a sensor, the output of which is connected to the first input of the adder, a control signal generator, the output of which through the first key is connected to the second input of the adder, the output of which is connected through the measuring transducer to the input of the threshold element, while the control input of the first key connected to the start input of the device’s self-monitoring, it is additionally equipped with two two-threshold comparators, a D-trigger, an And element, second and third keys, a delay element and two inverters, the inputs of the two-threshold comparators connected to the output of the measuring transducer, the output of the threshold element connected to the clock input of the D-trigger, the output of the first two-threshold comparator with the D-input of the D-trigger, the output of which is connected to the first input of the element And, the second input of which is connected with the output of the second two-threshold comparator, and the output is connected through the second key to the output indicating the health of the device, as well as through the first inverter and the third key connected to it in series - with Odom fault indication device trigger input self apparatus through a second inverter connected to the input of D-resetable flip-flop and via a delay element - to the control inputs of the second and third keys.

 Comparison with the prototype shows that the inventive device is distinguished by the presence of new units: two two-threshold comparators connected in series by a D-trigger, an And element and a second key, two inverters, a third key and a delay element, and their connections with other circuit elements.

 The proposed device for monitoring the technological parameter has increased control over operational checks of its performance due to the increased accuracy and reliability of the control of technical characteristics, which is achieved by automating the processing of verification results. This property is a significant difference between the proposed device and the known signaling devices, including the prototype.

 The drawing shows a block diagram of a device for monitoring a process parameter.

 A device for monitoring a process parameter comprises a sensor 1 connected in series, an adder 2, a measuring transducer 3, a threshold element 4 controlling an external actuating element (not shown in the drawing), a control signal generator 5 and a key 6 connected in series to the second input of the adder 2, and the control input is connected to the input of the device’s self-monitoring start, a two-threshold comparator 7 and a similar two-threshold comparator 8, the inputs of which are connected in parallel to the output a measuring transducer 3 connected in series by a D-flip-flop 9 and an And 10 element, the D-input of the D-flip 9 connected to the output of a two-threshold comparator 7, the synchronizing input of the D-flip-flop 9 to the output of the threshold element 4, and the second input of the And 10 element to the output of the two-threshold comparator 8, the inverter 11, the input of which is connected to the control input of the key 6, and the output to the zeroing input of the D-trigger 9, the inverter 12, the input of which is connected to the output of the element And 10, the delay element 13, the input of which is connected to the control key input 6, switch key 14 tion signal "Apparatus OK" key 15 and the switching signal "Failure apparatus", and an information input key 14 is connected to the output of inverter 12, and the control inputs of these switches are connected in parallel to the output of the delay element 13.

 A device for controlling a technological parameter, mainly vibration of the body of a gas turbine engine, operates as follows. An electrical signal proportional to the current value of the monitored parameter at the installation site of the sensor 1 is fed to the first input of the adder 2 and then, from the output of the adder 2, to the input of the measuring transducer 3.

In the measuring transducer 3, the component that characterizes the technical condition of the control object (for example, the rotor component of the vibration of the gas turbine engine) is extracted from the input signal, brought to a given measurement scale, averaged and converted to DC voltage (U ₌ ) for indication and further processing.

 From the output of the measuring transducer 3, the DC voltage is supplied to an external indicator of the current parameter value and to the threshold element 4.

The logical level of the signal at the output of the threshold element 4 depends on the current value of the DC voltage U ₌ at its input. If the input voltage value of the threshold element 4 is lower than a predetermined level, then its output is set to the state of log.0, but if the value U ₌ is equal to or exceeds this level, then the output of the threshold element 4 is set to the state of log.1. The response level of the threshold element 4 is chosen equal to that voltage value U ₌ , which corresponds to the maximum permissible value of the controlled technological parameter.

 From the output of the threshold element 4, a signal about exceeding the maximum permissible value of the monitored parameter is fed to an external alarm board.

 Reliability of the control is provided by periodic performance checks. Such verification is carried out, for example, before each flight of an aircraft during the pre-flight preparation of its on-board equipment. At the same time, a log signal is sent from an external switching element, for example, from a self-control power button located on the dashboard in the cockpit. 1 (instead of log.0 with the self-monitoring system disabled) to the control input of key 6.

 The result of the test is issued in the form of signals "Hardware is OK" or "Hardware Failure" to the corresponding external indicators when the control button is pressed after the length of time necessary for the test (2-10 s).

 All the while the control button is pressed and a log is present on the control input of key 6. 1, a calibrated test signal is connected (via key 6) to the second input of adder 2, the source of which is generator 5.

 Simultaneously with connecting the output of the generator 5 through the key 6 to the second input of the adder 2 log.1 from the control input of the key 5 is supplied to the inputs of the inverter 11 and the delay element 3.

 In this case, the signal at the output of the inverter 11 changes from log. 1 to log. 0. The same signal state (log.0) is also set at the zeroing input of the D-flip-flop 9. Thus, before the start of the test (at the control input of the key 6, the signal is log.0), a log is present at the output of the inverter 11 and the zeroing input of the D-flip-flop 9. 1, and the output of the latter is in the state log.0 regardless of the signal levels at its D-input and synchronizing input. At the beginning of the test and the whole time of the test (the time when the control input of key 6 is log.1) at the zeroing input of D-trigger 9 log.0. In this mode, the D-trigger is controlled by the D-input and the synchronizing input, and if during the test the signals at these inputs do not change, then the status of log.0 is saved at the output of the D-trigger 9.

 The delay element 13 sets the length of time from the start of the test (log.1 arrives at the control input of the key 6) to the end of the transient process in the device blocks when it is checked. Log.1, received at the input of the delay element 13, appears at its output after a given period of time. At the end of the test (releasing the control button and the appearance of log.0 at the control input of key 6), log.0 at the output of delay element 13 is set almost simultaneously with the opening of key 6.

 Thus, immediately after putting the device into the test mode of its operability, the output signal of the generator 5 through the key 6 is fed to the second input of the adder 2, the D-trigger 9 is put into operation and the delay element 13 starts the delay time.

The control signal of the generator 5 from the second input of the adder 2 passes through the adder 2 and the measuring transducer 3 and enters the output of the latter in the form of a DC voltage U ₌ , the value of which gradually changes from zero (at the time of the start of the test) to the steady-state value U ₌ = U _VK (after the end of the transition process). This voltage is supplied in parallel to the inputs of the threshold element 4, two-threshold comparator 7 and two-threshold comparator 8.

When the output signal of the measuring transducer 3 U ₌ U _cf equal to the value of the reference voltage of the threshold element 4, the latter is triggered, the signal at its output changes from log 0 to log 1, and this change (difference) of the logical state is fed to the synchronizing input D-flip-flop 9. The state of the output signal of the D-flip-flop 9 after passing the logical state difference at its synchronizing input is determined by what signal level (log.0 or log.1) was at its D-input at the moment of the occurrence of this difference, h then, in turn, is determined by the level of the logical signal at the output of the two-threshold comparator 7.

The two-threshold comparator 7 is a threshold circuit with two fixed response levels determined by the specified reference voltages e ₁ and e ₂ . These reference voltages are set so that the value of e ₁ corresponds to the lower limit of tolerance for the voltage level U ₌ at which the alarm should be triggered, and the value of e ₂ corresponds to the upper limit of this tolerance. The output of the two-threshold comparator 7 is in the state log.0 if the value of the DC voltage at its input is less than e ₁ or exceeds e ₂ . If the value of the input voltage of the two-threshold comparator 7 is equal to one of these reference voltages or is between them (e ₁ ≅ U ≅ e ₂ ), then its output is set to log.1.

In a working signaling device at the moment of triggering of the threshold element 4, the value of the output voltage (U ₌ U _cf ) is within the specified tolerance (e ₁ ≅ U _cf ≅ e ₂ ) and at the output of the two-threshold comparator 7, the state is log. 1. Since the D-trigger 9 captures at its output the state of the signal at the D-input at the moment the alarm is triggered (the differential has passed at the synchronizing input), its state is set to log.1, which remains until the end of the test.

To confirm the health of the device, in addition to checking the correspondence of the output voltage level U ₌ at which the alarm is triggered, to the specified tolerance, the compliance with the tolerance and the conversion coefficient of the adder 2 and the measuring transducer 3 (K _CR ) connected in series is checked.

During the test, the signal calibrated in amplitude from the output of the generator 5 U _gen is supplied to the second input of the adder 2 through the key 6. Since K _CR = U _VK / U _{1 VN} , and the value of U _{gene is} fixed, then to assess the correspondence of the value of K _{CR to} its acceptable values, it is sufficient to determine the correspondence of the output voltage U _{VK to the} tolerance for this voltage.

Matching (or matching) the values U _cr admissible values fixed by a window comparator 8, whose scheme is analogous to Scheme two-threshold comparator 7, and the value of its reference voltages e ₃ and e ₄ are selected so that at values U _=, located within a tolerance on its steady-state value, the condition e ₃ ≅ U ≅ e ₄ was satisfied and the state log.1 was established at the output of the two-threshold comparator 8.

Since the condition e ₃ ≅ U _vk e ₄ is satisfied in a working device, by the time the transition process ends, the state of log 1 is set at the output of the two-threshold comparator 8. Log 1 goes to the second input of AND 10, the first input of which is already set log.1 from the output of D-flip-flop 9. In this case, the output of the And 10 element goes into the state of log.1, and the output of the inverter 12 connected to it goes into the state of log.0.

 At the same time, log.1 from the output of the delay element 13 is supplied to the second (control) inputs of the keys 14 and 15. The keys 14 and 15 are closed and the logical signals from the outputs of the element And 10 and the inverter 12 are fed to the outputs of the “Equipment is OK” device (via key 14) and “Hardware Failure” (via key 15) to display the result of the test.

 The proper state of the device corresponds to the levels: log.1 - at the output "Hardware is OK" and log.0 - at the output "Hardware Failure".

If the device is faulty, then one of the conditions, e ₁ ≅ <N> U _cf e ₂ or e ₃ ≅ U _vk e ₄ , is not satisfied.

When decreasing the value of K _CR below the permissible level, the steady-state value U ₌ does not reach the lower boundary of the tolerance zone (U _VK <e ₃ ), at the output of the two-threshold comparator 8, the state is log.0 and after the keys 14 and 15 are closed, the outputs of the element And 10 and the inverter 12 indicate a failure of the device - the signal Log.0 is sent to the output of the device “Equipment is OK”, and the signal log.1 is sent to its output “Device Failure”, which allows to establish the presence of a malfunction.

When the value of K _PR exceeding the upper limit of tolerance (U _VK > e ₄ ), the device works similarly. In this case, by the time of closure of the keys 14 and 15 at the output of the two-threshold comparator 8, the log status is also set. 0 and the outputs of the device “Hardware is OK” and “Hardware Failure” receive signals log.0 and log.1, respectively, indicating a malfunction.

The device is also faulty if the alarm level U _cf does not correspond to the permissible values: U _cf <e ₁ or U _cf > e ₂ . In both of these cases, at the moment of triggering of the threshold element 4, the voltage value U ₌ = U _cf falls outside the tolerance zone determined by the values of the reference voltages of the two-threshold comparator 7 e ₁ and e ₂ . D-trigger 9 captures the status of the log. 0 at its D-input at the time of the signal difference at the synchronizing input and at its output, log.0 is stored. At the same time, the outputs of the element And 10 and the inverter 12 are stored respectively log.0 and log.1, which indicates a malfunction of the device.

After checking (releasing the start button for self-monitoring and the signal at the control input of key 6 to the state log.0), the output of the delay element 13 goes into the state log.0, the keys 14 and 15 disconnect the outputs of the element And 10 and the inverter 12 from the corresponding outputs of the device, the output of the inverter 11 goes into the state log.1 and puts the output of the D-trigger 9 in the state log.0, the key 6 disconnects the output of the generator 5 from the second input of the adder 2 and the value of the output voltage of the measuring transducer 2 U ₌ smoothly changes from the value of U _VK to zero . Thus, the device returns to its original state.

Claims (1)

 DEVICE FOR CONTROL OF A TECHNOLOGICAL PARAMETER, comprising a sensor, the output of which is connected to the first input of the adder, a control signal generator, the output of which through the first key is connected to the second input of the adder, the output of which is connected through the measuring transducer to the input of the threshold element, while the control input of the first key is connected with the input of starting the device’s self-control, characterized in that, in order to increase the reliability of the control, two two-threshold comparators, a D-trigger, an And element, are introduced into it the third and third keys, a delay element and two inverters, while the inputs of the two-threshold comparators are connected to the output of the measuring transducer, the output of the threshold element is connected to the synchronizing input of the D-trigger, the output of the first two-threshold comparator is connected to the D-input of the D-trigger, the output of which is connected to the first input of the element And, the second input of which is connected to the output of the second two-threshold comparator, and the output is connected through the second key to the output indicating the health of the device, as well as through the first inverter and connected to it sequentially, the third key is with the output of the device failure indication, the input for starting the device self-control through the second inverter is connected to the resetting input of the D-trigger and through the delay element to the control inputs of the second and third keys.