SU943523A1 - Comparator for line standard meter calibration checking - Google Patents

Description

one

The invention relates to a measurement technique and can be used in precision machine-tool construction and instrument-making in measuring the difference in lengths of stroke measures of length.

A known comparator for testing bar-shaped measures of length, comprising a base, an object table, mounted on a base with the possibility of reciprocating movement and intended to establish an exemplary and measurable bar-measure of length, is an optical-mechanical meter, representing, is a sight and counting microscopes connected between themselves and enshrined on the basis of GP,

However, the known device has a low productivity of measuring the difference in lengths of the linear measures of length.

The closest technical solution to the present invention is a comparator for testing

line length gauges containing an object table with a measuring position, an optoelectronic meter consisting of a signal generator of an exemplary line length measure, a photoelectric microscope located above the measurement position and a control computer connected by two inputs to the output of the signal generator, an exemplary line measure 9 parts and a photoelectric microscope, an electric drive connected to the control machine, and a carriage for the relative movement of the stage

15 and an optoelectronic meter connected to the output of the electric drive 21,

The disadvantages of such a comparator are poorness, insufficient

20 accuracy and performance of calibration due to the presence of two photovoltaic microscopes and an exemplary bar-shaped measure of length, errors arising from the errors of the relative position of the model and calibrated bar-shaped measures of length and the axes of the photoelectric microscopes; errors in applying strokes of an exemplary stroke measure of LENGTH, waste of time on the installation of sample stroke measures of length when moving to another step of a checkable stroke measure of length. In addition, this co-parator does not fully utilize the speed capabilities incorporated in the opto-electronic units, since in the course of the calibration of dashed measures of length frequent short-term stops of the sample table are required (in order to guide the dash measures to exact and durable measures of length) and long-term stops an object table (for changing turnable line measures). The verification performance is also insufficient due to the obligatory requirement of calibration of stroke length measures for two passes (in the forward and reverse direction) and averaging of the results of verification. The purpose of the invention is to simplify the design, improve the accuracy and performance of calibration. The goal is achieved by the fact that in a comparator for calibration of stroke length measures containing an object table with a measuring position, an optoelectronic meter consisting of a signal conditioner of an exemplary stroke length measure, a photoelectric microscope located above the measurement position, and a control computer connected by two inputs to the outputs of a signal generator, an exemplary dashed measure of length, and a photoelectric microscope, an electric drive connected to a control computer the carriage and the carriage for the reciprocal movement of the object table and the optoelectronic measurement tel connected to the output of the electric drive, the signal generator of the exemplary dashed measure of length is made in the form of a waiting tunable pulse generator of a stabilized frequency and a sensor of the speed of movement of the carriage connected to the input of the waiting a stabilizing frequency pulse generator, which is connected to the second and third inputs to the additional outputs of the control computer. In addition, the goal is achieved by the fact that the measuring position is made in the form of a removable rotary drum with base surfaces in the form of grooves for accommodating adjustable stroke length measures connected by a shaft to the second output of the electric drive, while the slots of the removable rotary drum are on its side surfaces along its surfaces, and the object table is made with a groove for accommodating a removable rotary drum, supports for its shaft located on the sides of the groove of the object table, and a lock position Yeni swivel drum; The photoelectric microscope is made with a double-image optical system, the control computer is made according to a circuit containing an electronic counting unit connected by two inputs to the outputs of a stand-by tunable stabilized frequency pulse generator and a photoelectric microscope, the control unit connected by a first input to the first output of an electronic the counting unit, the second input - with the output of a waiting tunable pulse generator of a stabilized frequency, the third input - with the output of a photo electric microscope, the first and second outputs - with the inputs of the electric drive, the third and fourth outputs with the second and third inputs of the waiting tunable generator pulse at a stabilized frequency, and the fifth and sixth outputs - with the third and fourth inputs of the electron-counting unit, the recording unit connected by the first the input with the seventh output of the control unit, and the second input with the second output of the electronic counting unit; the electronic counting unit is made according to the scheme containing a pulse frequency multiplier connected by the input with the output of a tunable adjustable frequency pulse generator with a stabilized frequency, an assembly circuit connected by a first input to the output of a tuning tunable waiting generator with a stabilized frequency, and a second input to the fifth output of the control unit, a delay line connected to the output of the photoelectric microscope, and the output to the first the input of the control unit, the sign analyzer connected by the first input to the output of the assembly circuit, and the second input to the output of the delay line, the time interval generator is connected the first input with the output of the assembly circuit, and the second input with the output of the delay line, the second assembly circuit connected with the fifth and sixth outputs of the control unit by the coincidence circuit connected with the first input with the output of the pulse frequency multiplier, the second input with the first analyzer output the third input matches the first input to the output of the pulse frequency multiplier, the second input to the second output of the sign analyzer, and the third input to the output of the time interval time slot, reversible pulse counter, connected by the first input to the output of the second assembly circuit, the second input to the output of the first coincidence circuit, the third input to the output of the second matching circuit, and the output to the second input of the registration unit. FIG. 1 shows a block diagram of a comparator for calibrating bar-shaped measures of length, FIG. 2 is a circuit of an electron-counting unit; FIG. 3 is a timing diagram of signals and a comparator for calibrating bar-gauge lengths. The comparator for calibration of stroke length measures contains placed on the base 1 subject table 2 with a measuring position, an optoelectronic meter 3 consisting of a former + signals of an exemplary stroke measure of length, a photoelectric microscope 5 located above the measuring position, and a control computer 6 connected the first and second inputs, respectively, with the outputs of the imager k signals exemplary dashed measures of length and photoelectric microscope 5, the actuator 7, connected to the first and the second outputs of the control computer 6, and the carriage 8 for the mutual movement of the object table 2 and the optoelectronic meter 3 connected to the output of the electric drive 7. The signal former of the exemplary dashed measure of length is made in the form of a waiting tunable generator 9 of stabilized frequency pulses and a sensor 10 of the speed of movement of the carriage 8, connected by an output to the input of the waiting generator 9-pulses of a stabilized frequency, which by the second and third inputs are connected to the third and fourth output control computer 6. The measurement position is made in the form of a removable rotary drum 1 1 with base surfaces in the form of grooves 12 for placing rotatable stroke measures 13 lengths connected by shaft C to the second output of the electric drive 7, while the grooves 12 of removable rotary drum | 11 is made on its side surface along its generators, and object table 2 is made with a groove 15 for accommodating a removable rotary drum 11, supports 16 and 17 for its shaft Tt, located on the sides of the groove 15 of the subject table 11, and fixing Hur angular position not shown removable rotary drum 11. The carriage 8 is bonded with electrically 7 via the lead screw 18. The photoelectric microscope 5 may be formed as a single optical system with an image stroke, and an optical system imaging the double stroke. The control computer (if used in the comparator to calibrate bar-based measures of the length of the photoelectric microscope 5 with the optical system of the double image of the stroke) is performed according to a simplified circuit containing an electronic counting unit 19 connected by two inputs to the outputs of the waiting tunable generator 9 of a stabilized frequency and a photoelectric microscope 5, control unit 20, connected by the first input to the first output of the electron-counting unit 19, the second input - to the output of the waiting tunable g 9 pulse generator of stabilized frequency, the third input - to the output of the photoelectric microscope 5, the first and second outputs - to the inputs of the actuator

7, the third and fourth outputs with the second and third inputs of the standby tunable generator 9 pulses stabilized frequency, and the fifth and sixth outputs with the third and fourth inputs of the electronic counting unit 19, the registration unit 21 connected by the first input to the seventh output of the control unit 20, and the second input - with the second output of the electron-counting unit E

The electronic-counting unit is made according to a circuit containing a pulse frequency multiplier 22 connected by an input to a stand-alone tunable generator 9 of a stabilized frequency, an assembly circuit 23 connected by a first input to an output of a stand-by tunable generator 9 of a stabilized frequency pulse, and the second input is to the fifth output of the control unit 20, a delay line 2 connected by an input to the output of the photoelectric microscope 5, and an output to the first input of the control unit, an analyzer

25 characters, connected by the first input to the output of the assembly circuit 23, and the second input to the output of the delay line 2k, shaper 2b of the time interval between signals of an imaginary exemplary bar-shaped measure of length and signals of a checkable dash measure of 13 length (hereinafter shaper 26 of the time interval connected by the first the input with the output of the assembly circuit 23, and the second input with the output of the delay line 2k, the second assembly circuit 27 connected by the inputs to the fifth and sixth outputs of the control unit 20, the matching circuit 28 connected by the first input to the output ohm multiplier 22 pulse frequency, the second input - with the first output of the sign analyzer, and the third input - with the output of the imager

26 a time interval, a coincidence circuit 29 connected by a first input to an output of a multiplier 22 of a pulse frequency, a second input to a second output of an analyzer of 25 characters, and a third input to an output of a time interval generator 26, a reverse counter SL of pulses connected by a first input to an output of a circuit

27 assemblies, the second input — with the output of the matching circuit 28, the third input — with the output of the matching circuit 29, and the output with the second input

block 21 registration. In this case, the output of the reversible counter 30 pulses and the second input of the registration unit 21 are multi-bit, and the number of bits in them is the same and is determined by the maximum error value of the stroke of the check dashed measure 13 of length represented, for example, in binary-decimal code.

If the pending tunable oscillator 9 of the stabilized frequency pulses is made of the oscillator itself and a frequency divider installed at the generator output, then in the electron-counting unit 19 there is no need for the pulse frequency cleverly / inhabitant 22, the first inputs of the coincidence circuits 28 and 29 are connected directly with the output of the generator, and the first input of the circuit 23 of the Assembly is connected to the output of the frequency divider.

Comparator for calibration of stroke measures 13 length works as follows.

The first by counting (conditionally) calibrating the stroke measure 13, placed on the removable rotary drum 11, is set to the working position and fixed in this position by the angular position lock of the removable rotary drum 1 1. On the scale of the signal former 9, an exemplary stroke measure of the length by the frequency switch is set nominal frequency of impulses, pre-calculated from the condition of the nominal pitch adjustable

line measure. 13 of the length and speed of movement of the carriage 8 (this frequency corresponds to the frequency of the pulses that would be formed if there were sample samples in the comparator

Claims (2)

a linear measure of length and a photoelectric microscope mounted above it, mutually moving relative to each other at a given speed). The sources of stabilized supply voltage of the comparator are included to calibrate the bar-shaped measures 13 of length. The sources are not shown in Fig. 1. With this signal, the electric drive 7 is turned on from the first output of the control computer 6, which moves the carriage 8 by means of the lead screw 18. As a result, the reciprocal movement takes place the subject table 2 and the photoelectric microscope 5. In the process of this movement, there is a periodic change in the light flux supplied from the light source of the photoelectric microscope 5 on the surface emoy power metal bar 13 measures the length, and the output of the photoelectric microscope ivyh.5 signals 5 are formed in the form of short pulses, one of the characteristic points which, for example, the inflection point on the time axis corresponds to the middle of strokes on a linear axis. This sequence of pulses (, to the second input of the control computer 6, which extracts the pulse Uftbix-fed from it) corresponds to the zero-left stroke on the length of the length gauge measure 13, and sends it from the second output to the second input of the waiting tunable generator impulses of stabilized frequency; From impulses Ugjjix. (, (the waiting tunable generator 9 of stabilized frequency pulses starts and generates a sequence calibrated in time and amplitude of pulses (Jjufj.gc with a higher nominal frequency. During movement of the carriage 8, speed sensor 10 measures its speed. Movement corresponding to speed movement of the carriage 8 is fed to the first input of the standby tunable generator 9 of a stabilized frequency and adjusts its frequency in accordance with the change in the speed of movement of the carriages 8. The sequence of short pulses .9 of the output of a stand-alone tunable generator 9 of stabilized frequency pulses is fed to the first input of the control computer 6, which further performs the following operations: delays the sequence of pulses of the checked dashed measure 13 length by the time jOA-i wherein the first pulse of this sequence is combined with the first pulse of the sequence of pulses of the waiting tunable generator 9 of the stabilized frequency signals; measures and analyzes for each stroke of the checked stroke length measure 13 the magnitude and sign of the deviation of its position from the position of the same stroke number on the specimen 10 exemplary stroke stroke measure, stores the value and sign of the deviation of each stroke of the stroke stroke measure 13 length in pr the stroke of the carriage 8, from output 1 switches the actuator 7 to return the carriage B to its original position} measures, analyzes and stores the value and the sign of the deviation of the position of each stroke of the check length 13 measure in reverse stroke e carriage 8 (in accordance with the requirements of GOST 8.131-7, 0.7); receives the arithmetic mean measurement result in the forward and reverse stroke of the carriage 8 of the deviation value of each stroke from the nominal position and records the averaged measurement results — upon completion of the calibration of the calibrated stroke measure 13 of length forms a signal Ug (, | xb (3 End of the measurement cycle, incoming to the third input of the tunable alternating generator 9 of a stabilized frequency and suspending the generation of pulses for the time required to rotate the removable rotary drum 11 by the angle ZbO ° / K, where K is the count The number of turning length measures 13, located on this reel 11i, generates a control signal from the fourth output to the actuator 7, which rotates the detachable turntable drum 11 and sets the working position of the next reversible stroke measure to length. The length measures taken are 13 measures that are similar to those described. After the calibration of all the lengths that are turned out, length measures 13 placed on a removable swivel drum 11, the comparator stops the measurement process. . At the same time, the removable swivel drum 11 with verified length length gauge measures is removed, and another removable swivel drum, C with other gauge length measures of length N, is mounted on supports 16 and 17. After that, a new calibration cycle begins. In the case of use in a comparator for calibration of bar-shaped measures of the length of a photoelectric microscope 5 with a double-image optical system, the process of calibration of bar-measures of length 13 is further reduced by a factor of two. The shortening of the calibration time of stroke measures 13 is due to the fact that in a photoelectric microscope 5 with a double-image optical system, a stroke image is formed with a symmetric distribution of illumination relative to the energy center of the stroke, i.e. In this case, the energy center of the stroke coincides with the geometric center of the stroke and the calibration of the stroke measure 13 is carried out in one stroke of the carriage 8. For this, the adjustable stroke measures 11 of the length are mounted on the removable drum 11 in such a way that the beginning of the subsequent checkable stroke measure 13 of length is set opposite the end of the previous checkable line measure, 13 length, and the beginning of the previous one opposite the end of the next one. In this case, it is possible to use both the serial computing machine 6 and the controlling computing machine 6 with a simplified execution scheme. Since the simplified controlling computing machine 6 has all the inputs and outputs, as well as the parameters of the input and output signals are the same as the serial control computer 6, then only the operation of the simplified control computer 6 will be described. This machine works as follows: from the control unit 20, stabilized supply voltages are included and a comparator for checking bar 11 measures length; in this case, the signal Un is generated at the fifth output of the control unit 20. . ) the measurement cycle, which goes to the third input of the electron-counting unit 19 (sets its elements 25, 26 and 30 to the initial position through the assembly circuits 23 and 27) and, at the first output, the control signal of the electric actuator 1, when arriving from photoelectric microscope output 8 signals Uau. From the third input, - - oQ o of the control unit 20, in the form of a sequence of short pulses, the latter extracts a pulse from it. appropriate. sends it to the second input of the waiting tunable oscillator 9 of stabilized frequency) when the Ugj i cHa signals from the output of the photoelectric microscope 5 to the second input of the electron-counting unit 19 are delayed by a 2k delay line at time MHt .jg and proceeding to the first input of the control unit 20 and the second inputs of the analyzer 25 of the sign and the imager 26 of the time interval between the signals of the test dashed measure of length 13 and the exemplary dash measure of length; when the shaper k signals Ugj ,, j arrive at the output of the electron-counting unit 19, they are multiplied h times by a multiplier 22 of the pulse frequency (converted into the ebix-li signal) and the assembly circuit 23 arrives at the output of the shaper k signals C / g, an exemplary stroke length measure to the second input of control unit 20, the latter generates control signals from them and other incoming signals at its inputs; a 25-character analyzer generates pulses Ugj ,, ,, 25 (-1 ) acc. A positive sign (when the step of the adjusted dashed line measures 13 length and a step of an exemplary dashed length measure) exceeds or coincides, and the pulses Ugjji ij ijy corresponding to a negative sign (at a step of the adjusted dashed length measure of 13 less than the step of the exemplary dash line length measure); The 26 time interval forms from the signals arriving at its inputs the time intervals .i, from the output of elements 22.25 and 26 of the signal ™ 8b1x.aa eych-15 nyh55 (a) .1b are fed to the corresponding inputs of the 28.29 coincidence circuits ( at the same time, depending on the sign As the error of applying the stroke of a checkable length stroke measure 13, the signals Ug are allocated, n "at the output of circuit 28 matches the positive error of applying the stroke of the scanned stroke measure of length 13, or signals C) d (, j at the output of the match circuit 29, corresponding to negative error the stroke of the checkable stroke measure 13 is the length, the signals I, O, the appearance of the measure arrive at the second and. the third outputs of the reversible counter 30 pulses and counted them (at the same time, a signal appears in its output, for example, in a binary-decimal code, corresponding to the magnitude and sign of the error of applying any dash of the adjustable dashed measure 13 length, which goes to block 21 the registration and the signal from the seventh output of control block 20 is recorded in it) after registering in block 21 of the registration of the magnitude and hcnac of the error of applying a particular stroke of the check point length measure 13 from the previous output of control block 20 to the assembly 27 a signal comes from a single measurement unit that passes it and sets the reversible counter of 30 pulses to the zero state (thereby preparing it to measure the error of the subsequent stroke with a stroke measure of 13 length) - after the end of the calibration of all strokes the stroke measure 13 of length by the control unit 20 generates, with a signal Ug (jin ciQ () f oorBejcrByKnn i Ugjji.n "which comes from its fourth output to the third input of the tunable alternator 9 pulses of a stabilized frequency and stopping The pulse generation for the specified time T p-, rotation of the removable rotary drum 1 is carried out from the electric drive 7, controlled by a signal from the fourth output of the control unit 20. The effect of the invention in comparison with the known comparators for calibration of stroke length measures is to significantly simplify the design and to improve the accuracy and productivity of calibration of stroke length measures more than. 1, 5 times. Claim 1. Comparator for calibration of bar-shaped measures of length, containing an object table with a measuring position, an optoelectronic meter consisting of a signal generator of an exemplary bar-shaped measure of length, a photoelectric microscope located above the measuring position, and a control computer connected to two inputs with outputs of the signal conditioner exemplary bar length measure and photo electric microscope, electric drive connected to the control computer, and carriage d the reciprocal movement of the object table and an optoelectronic meter connected to the output of the electric drive, characterized in that, in order to simplify the design, increase the accuracy and performance of the calibration, in it the signal generator exemplary dashed measure of length is made in the form of a waiting tunable pulse generator with a stabilized frequency and a sensor for the speed of movement of the carriage connected by an output with a lane; the input of the standby pulse generator of a stabilized frequency, which is connected to the second and third inputs to the additional outputs of the control computer. 2. A compensator according to claim 1, characterized in that the measuring position is made in the form of a removable rotary drum with base surfaces in the form of grooves for accommodating adjustable stroke length measures connected by a shaft to the second output of the electric drive, and the slots of the removable rotary drum are made on its side surface along its generators, and the object table is made with a groove for accommodating a removable rotary drum, supports for its shaft located on the sides of the groove of the object table, and a lock of the angular position of the otnogo drum. 3. A comparator according to claims 1 and 2, characterized in that the photoelectric microscope is made with an optical double-image system. 4. A comparator according to claims 1 to 3, characterized in that the control computer is made according to a circuit comprising an electronic counting unit connected by two inputs to the outputs of a stand-alone tunable pulse generator of a stabilized frequency and a photoelectric microscope, the control unit connected first time to the first output of the electron-digital unit, the second input with the output of a waiting tunable pulse generator of stabilized frequency, the third input the output of a photoelectric microscope, the first and second outputs - with the drive inputs, the relay and the fourth outputs - with the second and third inputs of the tunable stabilization frequency generator waiting for 15, and the fifth and sixth outputs - with the third and fourth inputs of the electronically counting unit, the recording unit connected with the first input to the seventh output of the control unit , and the second input - with the second output of the electron-counting unit. 5. The comparator according to claims 4 and 5, wherein the electronic counting unit is made according to a circuit containing a pulse frequency multiplier connected to the output of a tunable standby generator of stabilized frequency, cxeMi assembly, connected to the output of a waiting tunable the stabilized frequency pulse generator and the second input - with the fifth output of the control unit, the delay line connected to the output of the photoelectric microscope, and the output with the first input of the control unit, the analyzer sign a, connected by the first input to the output of the assembly circuit, and the second input to the output of the delay line, a time interval former connected by the first input to the output of the assembly circuit, and the second input to the output of the delay line, the second assembly circuit, connected with the fifth and the sixth output of the control block, the coincidence circuit connected by the first input to the output of the pulse frequency multiplier, the second input to the first output of the sign analyzer, and the third input to the output of the time interval generator, the second match the first input with the output of the pulse frequency multiplier, the second input with the second output of the sign analyzer, and the third input with the output of the time interval generator, a reversible pulse counter connected by the first input with the output of the second assembly circuit, the second input with the output of the first matching circuit, the third input is with the output of the second coincidence circuit, and the output is with the second registration unit. Sources of information taken into account in the examination 1.Fedotov A.I. Measuring devices of metalworking machines. Lenizdat. 19b7, p.251. 2.Alekseev P.P., Ka to L.K. Trishin N.V., Yachmentsev O.V. Automatic verification of subdivisions of stroke measures up to 1 m long. - Measuring equipment. 1970, No. 11, p. (prototype). th {lie t oH o ocfngoff / 7 / 7AV // r / 7 // "yA / 7M7 / V IPWVWl} V / if3 (f