SU832573A1 - Multichannel measuring device - Google Patents

Description

(54) MULTI-CHANNEL MEASURING DEVICE

one

The invention relates to devices for monitoring and evaluating the current state of an object and is used in the building materials industry as part of automated process control systems, diagnostic systems for the state of technological equipment, etc., including a human operator, and can also be used in other industries. as part of automated control systems for continuous technological processes and aggregates, which are monitored over many parameters .

A device is known which is multichannel and contains a series of sporadic control transducers, the number of which corresponds to the number of object dimensions monitored and the requesting voltage generator, the signal of which is simultaneously applied to the compensating inputs of all transducers of the sporadic control. The sporadic control transducers contain a null organ, to the inputs of which the output signals of the primary transducer, the requestor’s generator, are fed.

voltages and devices set the constant setting. The output relay signal of the zero-body is recorded by a light board, and digital information is recorded in memory cells.

In this device, the value of the constant setpoint is established, and the magnitude of the requesting voltage is recorded as a percentage of the non-revenue or output of the measured parameter beyond this setpoint. The use of such a device greatly facilitates the work of the operator 1.

However, for objects (processes)

5 nominal values of parameters, and also the limits of permissible values of parameters of which vary in the process of control, the proposed device has limited capabilities

0 and does not provide the required reliability control.

Closest to the proposed technical entity is a multi-channel measuring device,

5 containing a step-voltage generator, the output of which is connected to the first inputs of information channels, each of which is made on the converter

Claims (4)

0 of the sporadic control, the outputs of which are connected to the signal boards on the counter of the number of stages of increasing voltage, the first output of which is connected to the input of the digital indicator {2. A disadvantage of the known device is the inability to change the limits of measurement parameters, which limits the functionality of the device. The purpose of the invention is to expand the functionality of the device. The goal is achieved by introducing a control cycle setting unit into the device, the input of which is connected to the generator output of step-increasing voltage, and the output connected to the second inputs of information channels, the second and third outputs of the increasing voltage counter are connected respectively to the first and second inputs each information signal, a control block and a blocking node are entered in each information channel, the first and second inputs of the control block are connected respectively to the first and second inputs The first outputs of the control unit are connected to the first inputs of the sporadic control converter, the second input of which is connected to the measurement object, the outputs of the sporadic control converter are connected to the first inputs of the blocking node and to the third inputs of the control unit the second inputs of which are connected to the second inputs of the blocking node, the output of the blocking node is connected to the input of the incrementing counter for voltage, the null-indicators are inserted into the sporadic control converter, the master led values of tolerance, unit nominal parameter value, scaling unit, summation unit and subtraction unit, first inputs of the transducer of the sporadic control are connected to the first inputs of the scaling unit, the second input of which is connected to the unit of permissible deviation, the output of the scaling unit is connected to the first inputs the summation unit and the subtraction unit, the output target of the nominal value of a pair of meters is connected to the second inputs of the summation unit and the subtraction unit, the outputs of which are connected The first inputs of the corresponding zero-indicators, the second inputs of which are connected to the first input of the sporadic control converter, the outputs of the zero-indicators are connected to the corresponding outputs of the sporadic control transducer, the blocking node is made on the AND, OR elements, the first inputs of the blocking node are connected to the first inputs of the first elements AND and OR, one second input is connected to the second inputs of the first elements AND, the other second output of the blocking node is connected to the first input of the second element AND, the second inputs of which the first is connected to the outputs of the first OR elements, the outputs of the first and second elements AND are connected to the respective inputs of the second OR element, the output of which is connected to the output of the blocking unit, the control unit is made on the comparison element and two keys, the first input of the control unit is connected to the first inputs of the first and the second key, the second input of the control unit is connected to the first input of the comparison element, the outputs of which are connected to the second inputs of the corresponding keys and to the second outputs of the control unit, the outputs of the keys with the first outputs of the control unit, the third inputs of which are connected to the second inputs of the comparison element. . The drawing shows a diagram of the device. The device contains a sporadic control transducer 1, a step-rising voltage generator 2, a blocking unit 3, a control unit 4, a counter of the number of rising voltage levels 5, a digital indicator 6, a control cycle setting unit 7, a display 8 and 9, a unit 10 of permissible values deviation, scaling unit 11, unit 12 of the nominal value of the parameter, summation unit 13, subtraction unit 14, null organs 15 and 16, keys 17 and 18, comparison unit 19 for selecting the direction of tolerance change, first elements -And s 20 and 21, the second AND gate 22, the second OR element 23, the first OR elements 24 and 25 of the handle 26 of the request. The device works as follows. Let us consider the operation of a multichannel device for monitoring the state of an object on the example of the operation of a device for rapid assessment, constituting one channel of a multichannel measuring device. The work of the other channels is similar. In the initial position, the operator using the setting device 12 sets the nominal (optimal for this mode of operation of the object) value (Ots) of the monitored parameter, the current value of which from the object’s primary converter is fed to the inputs of the zero-bodies 15 and 16. Using the setting unit 10, the value of this mode of the object deviation parameter. At the output of the scaling and forming unit 11, the tolerance zone 11 produces a deviation signal (u), which is fed to the inputs of the summing 13 and subtracting 14 blocks. At the output of the summing unit 13, a signal is generated corresponding to the upper boundary of the tolerance zone, and at the output of the subtracting unit 14, a signal CC-D is produced, corresponding to the lower limit of the tolerance zone. The output of the 2-stage voltage generator is zero. Further, three cases are possible: the measured parameter Uj is within the tolerance zone. Ujf; The measured parameter Uy has reached the verge of the tolerance zone and the measured parameter U- has reached the lower boundary of the tolerance zone. If the measured parameter finds c within the tolerance zone, the signals of the O and control signals are generated at the outputs of the transducer 1 of the sporadic control, and the element of the selection of the direction of the change of the tolerance zone is set to the inverse state when both signals are present. key and opens the key 18. The operator manually using the query handle 26 or automatically starts the generator 2 of the step-increasing voltage. In this case, the output signal of block 7 of the monitoring cycle is set to zero the contents of the counter 5 of the number of voltage stages and locks the state of the device 19 for selecting the direction of change of the tolerance zone for the entire time of one monitoring cycle. LOS signals of both outputs of the pre-formist 1 of the sporadic control, fed through the elements OR 24 and 25 to the inputs of the element AND 2.2, and the signal from the inverse output of block 19, fed to the third input of this element and remove the blocking signal from the counting input of the counter 5. The step voltage signal through the open key 18 is fed to the second input of the scaling and forming unit 11 tolerance zone 11. As the requesting voltage increases, the counter 5 counts the number of its steps, and the value of the permissible deviation (D) at the input; de block 13 is proportionally reduced. The tolerance zone is narrowed until the value of the controlled parameter U does not coincide with the upper or lower boundary of the zone. Suppose that the parameter coincided with the upper boundary of the narrowed zone. The null-body 15 operates, the signal board 9 lights up, signaling that the parameter has gone beyond the upper boundary of the zone. The occurrence of signal i at the output of the null organ 15, through inverter 25, element 22 and element OR 23 blocks the counting input of counter 5. In counter 5, the magnitude of the parameter non-income to the tolerance zone, which is digitally recorded, is presented to the operator on the indicator 6. The appearance of the signal i at the output of the null organ 15, which enters the mode selection input of the device 19, does not change its state, since it is blocked by the control input for the duration of one monitoring cycle. The blocking signal of element 19 is removed when the query handle 26 returns to zero position, as well as when the voltage at the output of generator 2 is equal to zero. If the parameter goes beyond the upper or lower limits of the tolerance zone, a signal i appears at the output of the zero-body, respectively 15 and 16. Suppose that the parameter is out of the lower boundary of the zone and the null organ 16 has been triggered. At the same time, the signal board 8 has come on. Element 19 selection element for changing the tolerance zone on the second mode selection input will change its state and mc signal 1. In doing so, key 17 is opened, and key 18 is closed. The presence of a signal at the output of the element 21 removes the blocking from the counting input of the counter 5. A human operator manually or automatically starts the generator 2 of the step-increasing voltage. In this case, the output signal of the block 7 for-. Dani's cycle control resets to. zero is the contents of counter 5 and blocks the state of device 19 for the entire time of one monitoring cycle. The voltage arrives at the first input of the block 11 scaling and forming the tolerance zone. As the voltage rises, the counter 5 counts the number of its steps, and the value of the tolerance (e) at the output of the block 13 increases proportionally. The tolerance zone expands until the value of the monitored parameter coincides with the lower boundary of the zone. At the same time, at the output of the nullorgan 16, the Wits signal O, the Signal 8 will go out and, at the output of the element 21, the Wits signal O, the blocking counting input of the counter 5. The counter 5 records the amount of deviation from the lower boundary of the zone, which in digital form is presented to the operator on indicator 6. When the monitored parameter UX goes beyond the upper limit of the tolerance zone, the device works in the same way. In this case, the blocking of the counting input of the counter 5 is carried out through the element And 20. Thus, the proposed scheme, expanding the functionality of the device, allows to increase the reliability of control. Claim 1. Multi-channel measuring device containing a generator of foam-increasing voltage, the output of which is connected to the first and the information channels, each of which is made for the conversion of sporadic control, the outputs of which are connected to the signal board, on the counter of the number of rising voltage steps , the first output of which is connected to the input of a digital indicator, characterized in that, in order to expand the functionality of the device, a task block is entered into it control cycle, the input of which is connected to the output of a step-increasing voltage generator, and the output is connected to the second inputs of information channels, the second and third outputs of the voltage counter are connected respectively to the first and second inputs of each information channel, in each information channel the control unit is entered and the blocking unit, the first and second inputs of the control unit are connected respectively to the first and second inputs of the information channel, the first and the second outputs of the control unit are connected to the first the second inputs of the sporadic control converter, the second input of which is connected to the input of the device, the outputs of the converter of the sporadic control are connected to the first inputs of the blocking node and the third inputs of the control unit, the second outputs of which are connected to the second inputs of the blocking node, the output of the blocking node is connected to the input counter incremental steps on yarn. 2. The device according to claim 1, wherein the sporadic control transducer includes null indicators, a setpoint for the tolerance, a transmitter for the nominal parameter value, a scaling unit, a summation unit and a subtraction unit, the first inputs of the sporadic transducer control unit is connected to the first inputs of the scaling unit, the second input of which is connected to the unit of the tolerance, the output of the scaling unit is connected to the first, the inputs of the summation unit and the subtraction unit, the output Sensor nominal value of the parameter is coupled to second inputs of the adding unit and the subtracting unit, whose outputs are connected to first inputs of respective null indicator, the second inputs of which are connected to the first input transducer sporadic monitoring, null indicators outputs are connected to corresponding outputs of the converter control sporadic. 3. The device according to claim 1, characterized in that the blocking node is made on the elements AND, OR. the first inputs of the blocking node are connected to the first inputs of the first AND and OR elements, one second input is connected to the second inputs of the first AND elements, another second input of the blocking node is connected to the first input of the AND element, the second inputs of which are connected to the outputs of the first OR elements, the first and the second element And connected to the corresponding inputs of the second element OR, the output of which is connected to the output node of the lock. 4. The device according to claim 1, characterized in that the control unit is made on the comparison element and two keys, the first input of the control unit is connected to the first inputs of the first and second keys, the second input of the control unit is connected to the first input of the comparison element, the outputs of which are connected to the second inputs of the respective keys and with the second outputs of the control unit, the outputs of the keys are connected to the first outputs of the control unit, the third inputs of which are connected to the second inputs of the comparison element. Sources of information taken into account during the examination 1. USSR author's certificate No. 190236, cl. G 08 C 25/04. 2, Instruments and control systems No. 4, 1970, p. 26 (prototype). I i i i I I fo I