RU59801U1 - UNIVERSAL REFERENCE ELECTRIC DYNOMETER WITH A NAMED SCALE - Google Patents

Abstract

The inventive utility model relates to the field of testing equipment, specifically, to means of verification of working force measuring instruments.

The purpose of the claimed utility model is to simplify the design and expand the measuring range of the dynamometer.

This goal is achieved due to the fact that during calibration and calibration of devices for measuring force in the tension zone in the elastic element of the dynamometer, studs are screwed on both sides to fix it, and during calibration and calibration of devices for measuring force in the compression zone on the end of the elastic element of the dynamometer having a spherical surface, a support is installed, forming a spherical connection with the spherical surface of the elastic element; the output of the strain gauge force sensor through a normalizing amplifier with an additional control input is connected to the input of the analog-to-digital converter, the output connected to the input of the microcontroller, the task of which is to determine in which of the ten uniformly distributed sections of the load characteristic is the value measured by the analog-to-digital converter and its sign , the formation of the corresponding signal arriving at the control input and

changing the gain of the normalizing amplifier; The outputs of the microcontroller are connected to the control input of the normalizing amplifier and the dynamometer indicator, and the output of the normalizing amplifier in one measuring range of the dynamometer is directly connected to the input of the analog-to-digital converter, and in the other measuring range of the dynamometer it is connected to the input of the analog-to-digital converter through the amplifier with a five-fold gain.

Description

The inventive utility model relates to the field of testing equipment, specifically, to means of verification of working means of measuring force [1,2].

Known model portable tensile and compression dynamometers of the 3rd category mechanical type DORM, DOSM [3, 4], model electrical type DORE, DSSE [5, 6], standard electrical type DERE, DESE [7, 8], as well as universal mechanical type DOU-1 [9] and electric universal type DOU-3-I [10, 11].

Dynamometers of the DORM and DOSM type are an elastic element in the form of a steel cylindrical body with a mechanical measuring indicator of the clock type. Deformations that occur in the elastic element under the action of the load are transmitted by the intermediate mechanism on an enlarged scale to the indicator. Due to the nonlinearity of the elastic element, dynamometers have a conditional scale and are equipped with a calibration table.

A dynamometer of the DOU - 1 type is a steel closed square frame, inside of which a plate spring of complex shape is mounted, connected by an intermediate mechanism to a dial indicator. On opposite corners of the square frame there are supports for installing the dynamometer when checking the test machine in the compression area, and on the other two opposite corners of the frame there are devices for fixing the dynamometer with shanks in the grips of the test machine when

checking her tensile. It is also provided with a calibration table for both the tensile region and the compression region.

A dynamometer of the DOU-3-I type has a special purpose and is a set of two force sensors (tension and compression) and an electronic unit. The elastic element of the tensile force sensor is a metal plate with cutouts transverse relative to the axis of the applied force and strain gauges glued into them, and the sensitive element of the compression force sensor is made in the form of a membrane on the surface of which strain gauges are located.

The designs of dynamometers DORE, DOSE and DERE, DESE are in many respects similar. Dynamometers of the DORE and DOSE type are a strain gauge force sensor connected by a cable to the MITs-002 digital strain gauge. They have a margin of tolerance of measurement error of ± 0.5%. Dynamometers of the type DERE and DESE are a tensometric sensor for tensile or compression forces and an electronic unit interconnected by a cable. Unlike dynamometers DORM, DOSM, DOW-1, they have a named scale and the limit of permissible measurement error is ± 0.25%. The force sensor of the dynamometers DERE and DESE consists of an elastic tubular element with strain gauges glued to the working surface and integrated into a bridge circuit. The measured tensile force through the transition elements or the compression force through the ball bearing is transmitted to the elastic element, deforming it and the bridge strain gages. Electrical signals proportional to the measured force from the strain gauge bridge are fed to the input of the registration unit, where they are amplified, filtered, scaled and displayed on the digital indicator in named values.

When calibrating the testing machines with a standard (reference) dynamometer, it is installed in the grips in the case of tensile dynamometers or between the upper and lower plates of the testing machine

in the case of compression dynamometers, so that tensile or compressive forces applied to the dynamometer are directed along its axis. In accordance with [2], the dynamometer is loaded and unloaded with stops at 10 points corresponding to 10, 20, 30, 40, 50, 60, 70, 80, 90 and 100% of the limit value of the force measured by the dynamometer, after which the dynamometer readings and the load cell of the testing machine are compared and the measurement error of the testing machine is determined.

The closest analogue to the claimed device are standard dynamometers of the 3rd category of extension and compression of electric DERE and DESE [7].

The closest analogue, as well as the claimed utility model, has an elastic element in the form of a hollow metal rod, on the outside of which there are strain gauges forming a strain gauge bridge, a normalizing amplifier, an analog-to-digital converter, a microcontroller, and an indicator.

A disadvantage of the analogue is the need to have at least two electric dynamometers (tension and compression) with their own electronic units when calibrating and calibrating universal testing machines in tension and compression zones. The listed dynamometers have a measuring range from 0.1 to 1.0 of the largest limiting measured value of the dynamometer and, accordingly, only one of the measuring ranges of the force of the testing machine can be verified. To verify the entire range of force measurement from 0.02 to 1.0 of the limit value [12] in the zones of tension and compression using the considered dynamometers, their number should be at least four.

The purpose of the claimed utility model is to simplify the design and expand the measuring range of the dynamometer.

This goal is achieved due to the fact that during calibration and calibration of devices for measuring force in the tension zone in the elastic element of the dynamometer, studs are screwed on both sides to fix it, and during calibration and calibration of devices for measuring force in the compression zone on the end of the elastic element of the dynamometer having a spherical surface, a support is installed, forming a spherical connection with the spherical surface of the elastic element; the output of the strain gauge force sensor through a normalizing amplifier with an additional control input is connected to the input of the analog-to-digital converter, the output connected to the input of the microcontroller, the task of which is to determine in which of the ten uniformly distributed sections of the load characteristic is the value measured by the analog-to-digital converter and its sign , the formation of the corresponding signal arriving at the control input and changing the gain of the normalizing amplifier ; The outputs of the microcontroller are connected to the control input of the normalizing amplifier and the dynamometer indicator, and the output of the normalizing amplifier in one measuring range of the dynamometer is directly connected to the input of the analog-to-digital converter, and in the other measuring range of the dynamometer it is connected to the input of the analog-to-digital converter through the amplifier with a five-fold gain.

Thus, due to a change in the design of the elastic element and the use of a normalizing amplifier with a variable gain, switched in ten evenly distributed sections of the load characteristic and the use of an additional amplifier with a five-fold gain, we obtain a universal dynamometer that functions as two tensile and compression dynamometers with an extended measuring range.

The dynamometer device is illustrated by the structural diagram shown in the figure.

The universal reference electric dynamometer circuit includes a force sensor 1, a normalizing amplifier 2, an analog-to-digital converter 3, a microcontroller 4, an indicator 5, an amplifier 6 with a five-fold gain.

The force sensor 1 of the universal dynamometer has an elastic element in the form of a hollow metal rod with an internal thread on both sides and a spherical surface on one of the sides. On the outside of the rod are strain gauges forming a strain gauge bridge.

When using a dynamometer in the tension zone, studs are screwed into the elastic element to secure the dynamometer in the grips of the testing machine. When using a dynamometer in the compression zone, the latter is installed between the supporting plates of the testing machine through a ball bearing formed by the spherical surface of the sensor elastic element and the spherical bearing mating with it.

The normalizing amplifier 2 converts the differential input signal into a linear output voltage with a gain set by the microcontroller 4.

An analog-to-digital converter 3 converts the input voltage into a digital code supplied to the microcontroller 4, the task of which is to linearize the characteristics of the force sensor according to the calibration results at 10 calibration points and display the current value of the force on indicator 5.

Amplifier 6 with a five-fold gain is used to expand the measuring range of the dynamometer.

The differential signal from the output of the strain gauge of the force sensor 1 is fed to a normalizing measuring amplifier 2, which converts the differential signal into a linear voltage and its amplification. From the output of the normalizing amplifier 2, a signal proportional to the measured force is fed to the input of analog-digital

Converter 3 and is read from it already in digital form to the microcontroller 4 and then displayed on indicator 5.

The proposed dynamometer works as follows. When you turn on the dynamometer, the latter goes into verification mode. Verification mode - the main mode of operation of the dynamometer. In this mode, calibration of the working measuring instruments is carried out with a continuous indication of the current value of the force applied to the force sensor. The force value transformed by the force sensor 1 and previously scaled by the normalizing amplifier 2 in the form of a digital code is read by the microcontroller 4 from the analog-to-digital converter 3. After determining which of the 10 uniformly distributed sections of the load characteristic the received value belongs and what sign it has, the linearization coefficient is sampled from the table of linearization coefficients and the corresponding value is sent to the normalizing amplifier 2, where its coefficient y changes Ylenia.

To expand the measuring range of the dynamometer, an additional amplifier 6 with a five-fold gain was introduced, which is connected between the normalizing amplifier 2 and the analog-to-digital converter 3 during calibration of testing machines in the low-power range from 0.02 to 0.2 of the maximum ultimate load of the dynamometer. Range switching is performed by microcontroller 4 by applying a signal to the control input of amplifier 6, after which the output of the latter is connected to the input of an analog-to-digital converter. At the same time, the signal from the force sensor is additionally amplified by 5 times, which ensures the necessary 50-fold overlap of the measuring range of the verified test machine with one dynamometer [12].

Calibration of the dynamometer is carried out on a standard power measuring machine of the 2nd category. To form a table of coefficients

linearization is the memorization of the current values of the force measured by the dynamometer, at calibration points during sequential loading of the dynamometer on a force measuring machine. After the last point is fixed, which corresponds to the maximum value of the force of a particular dynamometer, the values of the calculated coefficients are memorized in the memory, which are equal to the ratio of the true value of the force in the verified point to the measured one.

The inventive dynamometer is free from the disadvantages of the considered analogues: the dynamometer force sensor has a simple design and an extended range of force measurement both in the tension zone and in the compression zone, provides verification of hydraulic and electro-hydraulic testing machines in the entire measurement range with one dynamometer.

In addition, the advantages of the proposed dynamometer include reading the force values in the named values, as well as the ability to integrate the dynamometer into the system of automatic verification and calibration of testing machines equipped with an electric force meter.

Used sources:

1. GOST 9500-84. Dynamometers exemplary figurative. General technical requirements. M. Publishing house of standards. 1984. S. 5.

2. GOST 8.287-78. Dynamometers exemplary figurative 3rd category. Methods and means of verification. M. Publishing House of Standards, 1979. P.10.

3. The state register of measuring instruments of the Russian Federation. Tensile and compression dynamometers exemplary portable 3rd category mechanical DORM and DOSM No. 15811-96, No. 15812-96.

4. Model portable dynamometers of the 3rd category of extension (DORM) and compression (DOSM) mechanical for testing testing machines and presses, http://www.mktsim.ru/product/dorm-dosm.html.

5. The state register of measuring instruments of the Russian Federation. Tensile and compression dynamometers exemplary portable 3rd category electric DORE-3-I and DOSE No. 15813-96, No. 15814-96.

6. Dynamometers exemplary portable 3rd category extension (DORE) and compression (DOSE) of the electric type. http://www.niktsim.ru/product/dore-dose.html.

7. The state register of measuring instruments of the Russian Federation. Tensile and compression dynamometers reference portable 3rd category electric DERE-3-I and DESE-3-I No. 25308-03.

8. Means of metrological support. Dynamometers reference portable 3rd category extension (DER) and compression (DESE). http://www.skbim.ru/.

9. Universal dynamometer DOU-1. http://www.vnir.ru/mesl 5537-html.

10. The state register of measuring instruments of the Russian Federation. Dynamometers universal exemplary portable 3rd category electric DOU-3-I No. 27202-04.

11. Universal electric dynamometer DOU-3-I. http://www.npfipo.ru/dore.html.

12. GOST 28840-90. Machines for testing materials in tension, compression and bending. General technical requirements. M. Publishing house of standards, 1991. S. 10.

Claims (1)

A universal reference electric dynamometer with a named scale, designed for verification and calibration of force measuring devices, containing a strain gauge force sensor with an elastic element in the form of a hollow rod with glued strain gauges and an electronic unit including a normalizing amplifier, analog-to-digital converter, microcontroller and indicator, characterized in that the output of the strain gauge force sensor through a normalizing amplifier with an additional control input is connected to the input of an analog-to-digital converter an output connected to the input of the microcontroller, the task of which is to determine in which of the ten evenly distributed sections of the load characteristic the value and its sign measured by the analog-digital converter are located, the formation of a signal corresponding to this, which arrives at the control input and changes the gain of the normalizing amplifier, the outputs of the microcontroller are connected to the control input of the normalizing amplifier and the dynamometer indicator, and the output of the normalizing amplifier in one the measuring range of the dynamometer is connected to the input of the analog-to-digital converter directly, and in another measuring range of the dynamometer is connected to the input of the analog-to-digital converter through an amplifier with a five-fold gain.