SU954913A1 - Plant for automatic checking of electromeasuring instruments - Google Patents

Description

The invention relates to a measurement technique and can be used in the construction of calibration systems. A device for calibrating electrical measuring instruments containing an input signal shaper, a reference signal source measuring the difference between the input and reference signals, capacitive sensors, the tips of movable pens of which are aligned with the middle of the calibrated scale marks, the maximum capacity recording unit and the indication unit of the calibration results, the input of the maximum capacity registration unit is connected to the output of the capacitive sensor, and the output is connected to the verification results indication unit 1. The disadvantage of this device is that the preparatory work, in particular the installation of capacitive sensors and; moving the tip of the movable feathers with i: the centers of the scale marks being scanned, take considerable time and low accuracy due to the use of capacitive sensors. automatic calibration of electrical measuring instruments, containing a reference signal source, an optoelectronic transducer unit (OZP), an OED displacement device, a unit. pulse drivers, a programming device, an error calculator, and a magnetic signal recorder, the first and second inputs of which are connected via a key device to a pulse shaping unit, and its outputs are connected to an error calculator 2. The disadvantage of this setup is a long calibration time. The purpose of the invention is to reduce the calibration time. 39 This goal is achieved by the fact that in an installation containing a reference signal source with an exemplary output divider, an optoelectronic converter unit with a block is moved and a pulse driver unit, an electronic key and a software unit whose two inputs are connected to the corresponding outputs of the pulse shaper unit, the first output to the input of the displacement unit, and the second to the control input of the model divider, an adder, an additional divider, an inverter, an analysis of the sign torus and a second electronic key are inputted The mmator is connected to a calibrated instrument, the first input to the exemplary divider, and the second and third inputs through the first and second keys are connected to the outputs of the inverter and an additional divider, the first input of which is connected to the output of the reference signal source, and the second to the third output of the program block The control inputs of the keys are connected via the character analyzer to the fourth output of the program block, and the input of the inverter is connected to the output of the additional divider. The drawing shows the block heme of the proposed installation. The installation contains a block 1 of optoelectronic drivers for converters including optoelectronic converters 2 and 3, a block k of pulse shapers containing drivers of 5 and 6 pulses, a program block 7, a block 8 of movement, an analyzer 9 of a symbol, electronic keys, 10 and 11 , signal inverter 12, 11 additional divider 13, reference signal source 1A, exemplary divider 15, adder 16 signals. The number 17 denotes the item being checked. The opto-electronic converter unit 1 serves to direct the luminous flux, reflected by 6 tons of significant marks and the pointer of the instrument 17 to electric pulses, and contain two optical-electronic converters 2 and 3 rigidly connected to each other, in the field of view of one of they fall on the significant marks of the scale, the other - the instrument pointer. The output of Each opto-electronic npecjC is connected to a block of k pulse-former. Both outputs of the block 4 pulse formers under 4 are clicked on the inputs of the program block 7; the program block 7 serves to set the algorithm of the plant operation depending on the technical characteristics of the scanned instrument 17 of the measurement limit and the number of significant marks). The program is entered into it either with the help of switches (buttons) or with punched cards. The program block 7 via the first output controls the block 8 of moving the optoelectronic converter unit along the scale of the instrument 17. The second output of the program block 7 controls, using the analyzer 9 characters, which switches the electronic switches 10 and 11 to the inputs the signal comes respectively either from the inverter 12 signals, or from the additional divider 13- The additional splitter 13 is connected to the output of the 1L source of the reference signal and its control- work. A program block .7- A controlled input of an exemplary divider 15 is also connected to the output of the source of the reference signal. The operating mode of this switch is set from program 7. The outputs of electronic switches 10 and 11, as well as the output of the exemplary divider 15 are connected to the corresponding inputs of the adder 1b signals whose output is connected to. input device 17. The principle of the proposed installation. In the proposed installation, a method of calibration of electrical measuring instruments is implemented, based on the use of a measure and an additional measure, which is rearranged discretely by an amount equal to the limit of the permissible absolute error of the instrument being turned. . Before starting the calibration, the program of the installation is entered into the program block 7, which includes a set of commands for the restructuring of the model divider 15 and the additional detritor 13. Commands sent to the model divider 15 are assigned its states for each significant mark of the instrument being scanned. As a result, at the output of the model divider 15, the specified signal values are set equal to the significant values of the scale of the instrument being checked. Commands from program block 7 to the additional divider 5 13 serve to set a signal at its output that is equal to the limit of permissible absolute error for a given rotatable device 17. At the same time, an inverted signal appears at the output of inverter 12 to the signal at the output of the additional divider 1 3-Installation operation begins at the operator's command and occurs in the next sequence. According to the program block 7, the displacement block 8 sets in motion the optoelectronic converter unit 1 and moves it until the light beam of the optoelectronic converter 2 of this unit hits the first significant point of the device being checked. 17- At this moment The optoelectronic converter 2 emerges a signal which, through the pulse shaper 5, is fed to the input of a software block 7, which stops the operation of the motion block 8. Thus, block 1 of optoelectronic converters is set against the first significant mark by turning the device on. 1 7 At the command from program block 7, the signal from the reference divider 15 is sent to the first input of the 16 signal, and the two other inputs of the adder 1b no signals. Hence, from the exit. The adder 16 at the input of the device 17 to be scanned receives a signal, the magnitude of which is equal to the significant scale mark, the device being scanned 17. As a result, there are three possible positions of the indicator relative to the digitized scale mark. In the first case, the pointer is positioned directly above the digitized mark. From the output of the optoelectronic converter 3, the pulse shaper 6 is fed to the second input of software block 7. A large pulse at the input of software block 7 indicates that the pointer is above the digitized mark, and the program block 7 generates a command for movement block 8, which moves block 1 of opto-electronic converters to the next digitized mark. In the second case, if the pointer of the device to be verified does not reach the 13 digitized mark, i.e. the second input of the program block 7 did not receive a signal from the output of the optoelectronic converter 3 through the pulse shaper 6, the program block 7 issues a command to the analyzer 9 characters that commute the electronic key 11 and the second input of the adder 16 receives a signal from the additional divider 13. the value of which is equal to the limit permissible absolute error of the device being checked 17. As a result, a signal arrives at the input of the device 17 being scanned, the value of which is equal to the sum of the signals from the output of the model divider 15 and the additional th divider 13- If, after supplying such an L, and driving an input device 17 to the input of the sensor 17, the optoelectronic converter 3 generates a pulse at the input of the program unit 1 through the pulse shaper 6, then the program unit 7 generates a command to translate the optical converter unit 1 to the next digital mark of the scale to be tested. If, however, the input of the program block 7 does not receive a signal that the pointer passes through a verified digitized scale mark, the verification process ends and the instrument rejects. In the third case, if the pointer of the instrument to be tested is passed through a verifiable digitized scale mark, i.e. the second input of the program block 7 received a signal from the output of the optical to electronic converter (1 3 through the pulse shaper 6, the software block 7 issues a command to the analyzer 9 characters, which switches the 10 m electronic key to the third input of the adder 16 receives a signal from the inverter connected the output of an exemplary divider is equal in magnitude to the limit of the permissible absolute error of the device being checked. 17 As a result, a signal arrives at the input of the device 17 being checked, the value of which is equal to the difference of the signals from the output of the model lithium 15 and additional divider 13. If, after supplying such a signal to the input of the scanned device 17, the optoelectronic converter 3 does not generate pulses at the input of the program block 7 through the pulse shaper 6, the program block

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7 forms a command to transfer block 1 of optical-electronic converters to the next digitized one. the scale mark of the instrument being checked. If, on the input of program block 7, a signal is received that the pointer passes through a verifiable digitized scale mark, the verification process ends and the instrument rejects. In a similar way, all the digitized marks of the scale of the instrument being checked are verified.

Thus, the proposed installation determines the finding of the absolute error of the instrument at all calibrated marks within the tolerance and the accuracy of the instrument, which significantly reduces the calibration time.

Claims (2)

1. USSR author's certificate №, cl. G 01 R 35/00, 1970. 2. USSR author's certificate number 266935, cl. G 01 R 35/00, 1968 15 /BUT It / J