RU2251115C1 - Four-wired simulator of discrete increment in resistance of resistance strain gauge - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: simulator has reference resistor, simulation range resistor, serial chain of N resistors of stairs, connected in parallel to range resistor, and switch. Chain of N resistor is connected in series with reference resistor. Current outputs of simulator have to be output of chain of N resistors and free output of reference resistor. Inputs of switch are connected to outputs of resistors of stairs. Simulation range resistor is connected in parallel to chain of N resistors of stairs. Free output of reference resistor has to be potential output of simulator. The other potential output of simulator has to be output of switch.

EFFECT: 150 times reduced error of simulation of increment of resistance.

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Description

The invention relates to electrical engineering and can be used to simulate the increment of resistance of strain gauges.

Due to the known advantages, the most common and universal type of measurement of various physical quantities (deformations, displacements, pressures, moments, forces ...) is electrotensometry. The number of measuring instruments used for these purposes amounts to hundreds of thousands. The metrological characteristics of these devices determine the degree of perfection of technological processes of industrial production, saving of raw materials, materials and energy resources, improving the quality of products and labor productivity in many branches of science, technology and leading sectors of the economy, including aircraft manufacturing, rocket engineering, mechanical engineering, shipbuilding, tractor manufacturing, automotive manufacturing, machine tool building, bridge building, instrument making, nuclear, metallurgical, chemical, oil, gas, coal, l Easy, food, paper, electrical industries, construction, transport, agriculture, medicine, trade ... The requirements for accuracy characteristics are constantly growing and in the near future the error of strain gauges and corresponding metrological tools, including simulators of increment of resistance of strain gauge sensors, should be reduced to values of the order of 0.01 ... 0.002% (Yu.S. Pliskin, A.P. Rakaev. Prospects for the development of devices for strain gauge sensors. Proceedings of NIKIMP, Issues of improving testing machines, instruments and means of measuring mass, Moscow, 1980, p. 92 ... 95).

The simulator of the discrete increment of resistance of strain gauge sensors is widely known, which is a reference resistor with parallel shunts (Horna O. Strain gages, M.-L., Gosenergoizdat, 1962, p. 154, Fig. 43). However, the accuracy of such a simulator is not high due to the significant influence of the resistances of the connecting and output conductors of the simulator.

Known are more advanced simulators of discrete increment of resistance of strain gauge sensors (with a supporting resistor and parallel shunts) included in the measuring circuit in a four-wire circuit (Beklemishev AI, Sudakov VA Device for automating research of metrological characteristics. Proceedings of TsAGI, issue 2105 1981, p. 75, fig. 3). Here, the influence of the resistances of the output conductors is excluded by the multi-wire inclusion of the simulator in the measuring circuit using potential and current output conductors. This principle has long been widely known and has been successfully applied in measurement technology. However, the influence of the resistance of the connecting element of the shunt with the simulator circuit, which includes the resistance of the connecting wire and the switching element of switching on the shunt, especially during the fast (of the order of several thousand per second) switching necessary for checking high-speed measuring instruments and systems, is a complex scientific and technical a problem. The requirement of high speed obliges us to use proximity switches of the type of MOS transistors to include a shunt in the measuring circuit of the simulator, which, with all their positive qualities, have significant open resistance. The best types of such domestic switching elements (the “590” series of microcircuits) currently have open-circuit resistance of about 70 Ohms (590KN5). At typical values in strain gauge (the resistance of the reference resistor is 120 Ohms; the range of simulated resistance increments of the strain gauge is 4.8 Ohms; the resistance of the switching element of the switch in the open state is 70 Ohms), the relative error in simulating the increment of resistance is 2.3%, which is unacceptable even for middle class measurements.

The closest in technical essence and the achieved effect to the proposed invention is a four-wire simulator of a discrete increment of resistance of the strain gauge, in which the shunts are connected through an additional resistor in series with the current output conductor of the simulator (RF Patent No. 2023979 “Simulator of a discrete increment of resistance of strain gauges”). With similar typical values in tensometry, the relative error in simulating the increment of resistance is 0.46%, which is not enough for accurate measurements.

The objective of the present invention is to improve the accuracy of simulating a discrete increment of resistance of a strain gauge.

The technical result of the invention is a significant, for example, an order of 150 times, reduction in the error of imitation of the increment of resistance of the strain gauge.

The solution of this problem and the technical result are achieved by the fact that in a four-wire simulator of a discrete increment of resistance of a strain gage with two pairs of terminals, each of which is a current and potential terminal of a simulator containing a reference resistor, one terminal of which is connected to one pair of terminals of the simulator, and a switch with N +1 inputs and one output, the other output of the reference resistor through a serial circuit of N pieces of resistors of the simulation stages is connected to the current output of another pair of outputs of the simulator , the potential output of which is connected to the output of the switch, and its inputs are connected in series with all the terminals of the serial circuit N pieces of resistors of the simulation stage, and an additional simulation range resistor is included, connected between the current output of another pair of outputs of the simulator and any output of the reference resistor.

The drawing shows a diagram of the inventive four-wire simulator of a discrete increment of resistance of the strain gauge.

The four-wire simulator of the discrete increment of the resistance of the strain gage (see drawing) has two pairs of terminals, each pair of which is the current “I” and potential “U” terminals of the simulator, and contains the reference resistor R0, N pieces of resistors R1 ... Rn of the simulation stages ( the purpose of which is the formation of the values of the simulation steps), switch K with N + 1 inputs and one output, the resistor R of the simulation range (the purpose of which is the formation of the simulation range). One pin of the reference resistor R0 is connected to one pair of pins of the simulator, and the other through a serial circuit N of pieces of resistors R1 ... Rn of simulation stages with the current pin of another pair of pins of the simulator. The potential output of another pair of outputs of the simulator is connected to the output of switch K, the inputs of which are connected in series with all the outputs of the serial circuit N pieces of resistors R1 ... Rn of the simulation stages. The simulation range resistor R is connected between the current output of another pair of simulator outputs and any output of the reference resistor R0.

A four-wire simulator of a discrete increment of resistance of the strain gauge works as follows.

The electric current I from the measuring device flows through the following circuit of the simulator: the current output of the simulator, a series circuit of resistors R1 ... Rn of the simulation stages, the reference resistor R0, and another current output of the simulator. Part Ir of the current I flows through the resistor R of the simulation range parallel to the circuit of resistors R1 ... Rn of the simulation stages with current Is.

That is: I = Ir + Is,

Where

I is the electric current from the measuring device flowing along the simulator as a whole;

Ir is the electric current flowing through the resistor R of the simulation range;

Is is the electric current of the resistors R1 ... Rn of the simulation stages.

The measuring device, at the input of which the simulator is switched on, “estimates” the resistance of the simulator Ru by the voltage drop U on it using its potential leads, and with a known (device) current value I flowing through the current leads of the simulator:

As a rule, the resistances of the resistors R1 ... Rn of the simulation stages are equal to each other.

Let be:

R1 = ... = Rn = Rs.

Then:

IrR = IsNRs;

From:

Then the voltage U of the simulator at the potential terminals at its mth stage (i.e., with the corresponding switch K turned on) has the form:

Moreover, m = 0, 1, 2, ... N and, accordingly, the numbers of the switch inputs. The resistance of the simulator, evaluated by the measuring circuit, into which it is connected according to a four-wire circuit, with its mth simulation stage is:

The increments of the simulator resistance at the mth simulation stage, therefore:

those. linearly depends on the number m of the simulation stage, which should be proved.

On the other hand, the range of the simulated increment of resistance of the simulator, which corresponds to its maximum level (m = N):

Hence: Δ RNRs + Δ RR = NRsR;

R (NRs-Δ R) = Δ RNRs;

Thus, with the known: the range of simulated increment of resistance, the number of simulated steps N + 1 and the selected resistors Rs of the simulation steps (convenient from the point of view of ensuring their high stability of the nominal resistance), it is easy to calculate the required resistance of the resistor R of the simulation range according to the above formula.

As for the error in simulating the resistance of a strain gage due to the presence of non-zero resistance of the key elements of the switch, the following should be noted. The resistance of the stage resistors Rs in strain gauge in simulators of a discrete increment of the resistance of the strain gauge is many (about 100 ... 200) times less than the reference resistor R0, which allows us to exclude them from consideration when evaluating the considered error in order to simplify the calculations. On the other hand, the input impedance of the measuring circuit Pc, which evaluates the output voltage of the simulator (these are usually the inputs of operational amplifiers), is very high (of the order of 10 ⁸ ... 10 ¹¹ Ohms), which allows us to neglect the resistance of the key elements of the switch, since they are turned on in an electrical circuit in series. Consider the simplest case when the switch, with its first input, transfers voltage to the simulator output from the corresponding output of the reference resistor R0. In this case, the input resistance Rc of the measuring circuit (to which the simulator is connected) is turned on in parallel with the reference resistor R0.

In the ideal case (when Rc = ∞), the simulator resistance:

Ru = R0.

In the real case, in the presence of a shunting action of the measuring circuit with a resistor Rc, the resistance of the simulator:

The relative error of simulating the increments of the resistance of the simulator is equal to the difference of the resistance of the real and ideal cases, referred to the range of the simulated increment of resistance:

At typical values for imitators of increment of resistance of strain gages: R0 = 120 Ohm, Δ R = 4.8 Ohm, Kts = 100 MΩ:

which is 157 times better than the prototype.

An additional significant positive effect should also be attributed to the fact that the resistors of the simulation steps here do not require the implementation of non-standard (usually unusual) nominal values of resistances - you can take any (slightly larger) close value of the resistance of the step and shunt the resistor circuit stages with one (calculated) resistor of the simulation range, and (which is also very important) this resistor determines only the range value, without affecting the reference rating of the simulator. This circumstance, in addition to economic benefits, has a significant positive effect on the stability of the obtained accuracy characteristics of the simulator during use.

In addition, for example, when simulating tensile strain gauges operating only in tension, the fact that the inventive simulator with respect to the reference resistor provides precisely the positive (in sign) effective increment of the simulator resistance, and not negative, as in most analogs.

It should be noted that the claimed effect of the invention can be obtained in the case when the simulation range resistor R is connected to the other output of the reference resistor R0, with the only difference that it will be necessary to calculate, in addition, the resistance value of the reference resistor itself, which will not equal to its resistance in the above case.

According to this proposal, the institute carried out the corresponding theoretical and experimental studies on the creation of specific simulators of the discrete increment of resistance of the strain gauge, which confirm the feasibility of the considered simulator and the possibility of obtaining the claimed technical effect.

The implementation of the proposal in the IMS for strength studies of aircraft structures will significantly increase the reliability of the test results, and therefore, the reliability of recommendations issued by the industry on improving the design of aircraft.

Claims (1)

A four-wire simulator of a discrete increment of resistance of a strain gage with two pairs of terminals, each of which is a current and potential terminal of a simulator, containing a reference resistor, one terminal of which is connected to one pair of terminals of the simulator, and a switch with N + 1 inputs and one output, characterized in that the other output of the reference resistor is connected through a serial circuit of N pieces of resistors of the simulation stages to the current output of another pair of simulator outputs, the potential output of which is connected to the output of the yuchatelya, and its inputs are connected in series with all pin serial circuit of resistors N pieces simulation stages, and a dummy resistor is additionally introduced simulation range is included between the current output terminals of the other pair and any simulator output reference resistor.