DE10336763B4 - Method for monitoring a measurement based on a resistive sensor, monitoring device and industrial scale - Google Patents

Abstract

Method for monitoring a measurement based on a resistive sensor (DMS) for detecting mechanical variables (F), in particular for weight detection, wherein a) a target impedance value (Zo) of the resistive sensor (DMS) at the measuring location is determined during commissioning, b ) a tolerance value (lim) is specified for a maximum permissible deviation from the nominal impedance value (Zo), c) a value (Z *) for the impedance (Z) at the measuring location of the resistive sensor (DMS) is continuously determined, and d) if an impermissible deviation of a current impedance value (Z *) from the nominal impedance value (Zo) an error message (FA) is output.

Description

The invention relates to a method for monitoring a measurement based on a resistive sensor for detecting mechanical variables, in particular for weight detection. The invention relates to a monitoring device for carrying out the method and an industrial scale, in particular for automation and manufacturing technology.

From the DE 30 20 423 C2 It is known to monitor a balance with connected in a strain gauge resistive sensors at the end of a weighing process and when the balance has come to rest, enter a test signal in the balance, process and then compare with a reference value, the review as successful is considered if the comparison result is within a tolerance range. To generate the test signal, an asymmetrical voltage is applied to the strain gauge bridge.

From the US 5,371,469 A For example, a measuring method is known in which a resistive sensor in series with a reference resistor is supplied with a constant current and the voltages occurring at the sensor and the reference resistor are measured and subtracted from each other to form a measurement result. The measurement result is therefore independent of any parasitic resistances in the path of the constant current.

During a manufacturing process, in particular during an automated technical process, accurate and reliable quantity or weight ratios z. B. to comply with the mixing of a chemical product or in a compilation of a building material. In order to be able to guarantee a high quality of such products in the context of a quality assurance system, exact, reliable and highly available industrial scales are necessary. Such scales can z. B. with an automation system in conjunction, which z. B. the filling process automatically ends upon reaching a predetermined filling quantity or a predetermined weight of a certain substance. The reliability and accuracy of weighing are therefore of particular importance.

Various measurement methods are known for weight measurement, with load cells based on strain gauges preferably being used in the industrial sector since they are robust, very accurate and durable. The strain gauges are z. B. applied to a bending rod, which bends by the action of force by the weight to be measured. This bending causes a proportional change in resistance in the meandering strain gauge. The change in the resistance is a measure of the bending and thus ultimately the weight to be measured itself. Generally, such a sensor is also referred to as a resistive sensor, in which the action of a physical quantity, such. As a force, pressure, light or temperature, etc., associated with a change in resistance.

Because of their high sensitivity and thermal stability is mainly a full bridge circuit with four strain gauges as a resistive sensor used, such. B. the well-known Wheatstone bridge circuit. As a so-called Vollbrucke the resistive sensor for excitement is usually operated by a voltage source with a constant voltage of a few volts. Typical values for the current consumption of the bridge circuit are z. B. 250 mA. To further increase the accuracy of several resistive sensors can be connected in parallel by z. B. several of them in a row or in a field on the o. G. exemplary bending rod can be applied. The parallel connection multiplies according to the current provided by the voltage source.

A high degree of enforcement of the manufacturing environment with electrical and / or magnetic interference fields due to a large number of control devices and in particular motor and electromagnetic actuators, etc., means that the sensor or the load cell has to be separated from the measurement evaluation unit via a shielded supply line. Preferably, this is then in a measuring room, which is particularly shielded against electromagnetic interference and in which all other important Messauswerteeinheiten for the manufacturing process are housed. Sensor and evaluation unit can be up to 100 m apart.

To avoid metrological effects of voltage drops over the supply line, four further lines are required in addition to the two lines for excitation of the bridge circuit or the resistive sensor. By means of these, the evaluation unit can pick up the exciter voltage present at the measuring location and on the bridge circuit as well as the measuring voltage virtually without power and consequently without loss. This electrical connection of the resistive sensor or the full bridge is also known by the term "6-wire technology".

Due to the harsh environment in the industrial environment, it may happen that z. B. breaks a supply line for the excitation of the full bridge or one of the returned conductors for tapping the exciter voltage. Such breaks could be determined by means of a threshold value monitoring.

However, it is not possible with the aforementioned threshold monitoring, z. B. to detect the failure of one of several parallel full bridges or resistive sensors. This has the disadvantage that it leads to incorrect measurements and consequently to incorrect fill quantities and weights of a substance. This is particularly critical when a plurality of full bridges is connected in parallel. If one of the resistive sensors fails, this leads to relatively small changes in the measuring voltage, such as. In the single-digit percentage range. However, this change is due to the high accuracy requirement of the o. G. to be weighed quantities and substances seriously, since the effects of the measurement error can be determined only after a longer period in quality assurance. The mixtures, substances or products produced in the meantime are unusable.

In another known monitoring method, a test resistor is connected in parallel in the transmitter via the lines to the sensor and determines the measurement signal change caused thereby. The disadvantage of this is that the signal acquisition must be interrupted during the test. Consequently, no measurements can be made for the actual manufacturing process.

The invention is therefore based on the object of specifying a method and a monitoring device for carrying out the method, which reliably detect and indicate measurement errors.

The object of the invention is achieved with a method for monitoring a measurement based on a resistive sensor for detecting mechanical variables, in particular for weight detection. In this case, a setpoint impedance value of the resistive sensor at the measurement location is determined during commissioning or during an exemplary cyclic calibration process, a tolerance value for a maximum permissible deviation from the nominal impedance value specified, continuously determined a value for the impedance at the measurement location of the resistive sensor and then at an impermissible deviation of a current impedance value from the nominal impedance value an error message.

This has the great advantage that without interrupting the actual weight or mass measurement and thus without any restrictions on the o. G. even slight deviations of the impedance of the sensor can be detected. If a measured impedance value differs z. B. from 1% of the nominal impedance value, so immediately an error message, and it can thus be initiated immediate countermeasures in manufacturing. It is thus also the failure of a resistive sensor in a plurality of parallel and / or series-connected resistive sensors, such as the aforementioned full bridge or Wheatstone bridge circuit with strain gauges recognizable.

Preferably, a current impedance value from a current applied to the resistive sensor excitation voltage and that at the measuring location, ie. H. in the sensor and directly on the resistive sensor, and determined from an associated exciter current.

It is also possible to measure an impedance value in such a way that only the exciter voltage applied to the resistive sensor is determined or measured. In order to finally be able to determine the impedance value by calculation, a constant current for exciting the resistive sensor is impressed into it. This can be z. B. be realized with a precision power source. Since the value of the constant current is known, the impedance value can be determined immediately and without further current measurement.

Another advantage is that, by the impedance measurement method described above, the adverse voltage drops across the line resistances in the leads have no effect on the measured value of the impedance. Also, temperature-induced changes in the line resistance or changes in contact resistance such. B. at the connection contacts of the measuring sensor advantageously have no effect on the measured value of the impedance.

In a preferred variant of the method, a current impedance value is determined on the basis of a ratiometric measuring method from exciter voltage and from a current measuring voltage corresponding to the exciter current. In this known measuring method, only the ratio of two measured variables is considered advantageous. Compared to the absolute measurement of measured values, this method is considerably more accurate.

In a further variant of the method, the same measuring principle is determined on the physical variable currently to be measured, in particular the mechanical variable such as force or pressure, from a measuring voltage applied to the resistive sensor at the measuring location and from the exciter voltage.

Finally, the force is output as a mechanical physical quantity to be detected, as a weight value or as a mass value. This value can be further processed as part of the manufacturing or automation process.

The object of the invention is further achieved with a monitoring device for carrying out the method according to the invention for one or more resistive sensors which can be interconnected in parallel with one another and which can be connected to the monitoring device via a supply line. In this case, the monitoring device has an A / D converter at least for detecting an exciter voltage applied to the sensor and an associated excitation current and a control unit which is connected to the A / D converter via a data line, such. As a data bus is connected. The control unit, such. As a microcontroller, further comprises first means which continuously determine a value for the impedance of the resistive sensor from the excitation voltage detected by the A / D converter, determine a difference between the currently determined impedance value and a predefinable target impedance value, and then Issue an error message if the difference exceeds a predefinable tolerance value.

For the actual measured value acquisition within the scope of a production or automation process, the A / D converter continues to record the measuring voltage applied to the resistive sensor. For data processing purposes, the control unit has second means which determine the ratio of measuring voltage and excitation voltage and then output a weight or mass value proportional to the ratio.

Preferably, a Wheatstone bridge circuit is connected to the monitoring device as a resistive sensor. The resistive sensor consists of at least one strain gauge.

As described above, particularly load cells with strain gauges are advantageous in the industrial sector, since they are robust, very accurate and durable.

Finally, several resistive sensors can be interconnected in parallel and / or in series with one another. The "wiring" then takes place in the sensor itself. In sum, the entire circuit thus corresponds to a single bridge circuit which can be connected via a supply line to the monitoring device.

The device according to the invention can be advantageously used in an industrial scale, in particular for automation and production technology, which has a load cell with at least one resistive sensor, wherein the load cell can then be connected to a monitoring device via a supply line.

The invention will be explained in more detail with reference to the following figures. It shows

1 FIG. 2 shows an example of a construction of a load cell with applied strain gauges on a bending rod, and FIG

2 : An exemplary functional diagram of the monitoring device according to the invention, to which a sensor with a resistive sensor is connected in a Wheatstone bridge circuit.

1 shows a known exemplary construction of a load cell WZ with applied strain gauges R1-R4, which are applied flat on a bending bar BS of the load cell WZ. The application can z. B. by means of an adhesive. The strain gauges R1-R4 are according to the example in 1 arranged so that all can actively participate in the formation of a measurement signal. This not only has advantages in terms of sensitivity, but also in terms of thermal stability. A uniform change of all resistances by temperature influences leaves the measurement signal unchanged when the four strain gauges R1-R4 shown in a Vollbruckenschaltung such. B. be "wired" in a Wheatstone bridge circuit DMS with each other. For reasons of clarity, the "wiring" of the strain gauges R1-R4 with each other is not shown. This shows the corresponding circuit in the following 2 ,

2 shows an exemplary functional diagram of the monitoring device AE according to the invention, to which a sensor SENS with a resistive sensor DMS is connected in a Wheatstone bridge circuit. Sensor SENS and monitoring device AE are connected by way of example via a supply line L with six conductors and via connection contacts. In the left image of the figure, the associated electrical circuit diagram of the resistive sensor DMS is visible. The strain gauges R1-R4 are thus shown as ohmic resistors. Furthermore, two electrical circuit symbols RL are shown by dashed lines in place of the distributed line resistances in the supply line L. Z denotes the impedance or the ohmic resistance of the resistive sensor DMS, which results when "looking" into the resistive sensor DMS at the measuring sensor SENS at a measuring location. US represents the actual output signal, ie the measuring voltage, which is subsequently evaluated. UD is the excitation voltage applied across the Wheatstone bridge circuit.

The monitoring device AE, shown in the right part of the figure, has, for example, a two-channel CH1, CH2 analog / digital converter ADC and a microcontroller C, which is the input side connected via a data link DV to the analog / digital converter ADC. The data connection DV can also be a bus connection. The entered arrow should essentially represent the main data direction. On the output side, the microcontroller C symbolically provides two lines for outputting a measured value for the measured weight F * or for the measured mass and for outputting an error message FA in the event of a measurement disturbance. The generation of the two signals F *, FA is effected by dot-dashed first and second means M1, M2 of the microcontroller C. The means M1, M2 are, for example, software routines. On the input side, the analog / digital converter ADC has an input for a reference voltage Uref. At the same time, as described above, this voltage Uref forms the one comparison part in the ratiometric measuring method and therefore corresponds to the voltage value of the excitation voltage UD. At the analogue input channel CH1 of the analogue-to-digital converter ADC, for the weight force determination F *, the second comparison variable is present, ie. H. the measuring voltage US on. Furthermore, the monitoring device AE has a constant voltage source with a voltage UV for exciting the resistive sensor DMS. IV denotes the self-adjusting exciting current IV through the resistive sensor DMS.

According to the invention, the exciting current IV is measured to measure the impedance Z. This is done in the example of the figure by means of a low-resistance measuring resistor RM, such. B. by means of a shunt. The drop across this resistor RM proportional current measuring voltage UM is read in via the second input channel CH2 of the analog / digital converter ADC and then further processed in the microcontroller C by the first means M1. These determine a calculated impedance value Z * from the ratio of the measuring voltage US to the current measuring voltage UM. By multiplication with the ohmic value of the measuring resistor RM, the determination is completed. Subsequently, the desired impedance value Zo is subtracted from this value Z *. If this difference exceeds a tolerance value lim, the output of an error message FA takes place immediately. The desired impedance value Zo and the ohmic value for the measuring resistor RM can be deposited electronically in the microcontroller C as constants.

Claims (11)

Method for monitoring a measurement based on a resistive sensor (DMS) for detecting mechanical variables (F), in particular for weight detection, wherein a) a target impedance value (Zo) of the resistive sensor (DMS) at the measurement location is determined during a startup, b) a tolerance value (lim) for a maximum permissible deviation from the nominal impedance value (Zo) is specified, c) continuously determining a value (Z *) for the impedance (Z) at the measuring location of the resistive sensor (DMS), and d) if an impermissible deviation of a current impedance value (Z *) from the nominal impedance value (Zo) an error message (FA) is output. Method according to Claim 1, wherein a current impedance value (Z *) is determined from an exciter voltage (UD) applied to the resistive sensor (DMS) at the measuring location and from an associated exciter current (IV). Method according to claim 2, wherein a current impedance value (Z *) is determined on the basis of a ratiometric measuring method from exciter voltage (UD) and from a current measuring voltage (UM) corresponding to the exciter current (IV). Method according to claim 2 or 3, wherein the mechanical quantity (F) currently to be measured is determined on the basis of a ratiometric measuring method from a measuring voltage (US) applied to the resistive sensor (DMS) at the measuring location and from the exciter voltage (US, UD). The method of claim 4, wherein the mechanical quantity (F) is a force whose detected value is output as a weight value (F *) or as a mass value. Monitoring device (AE) for one or more resistive sensors (DMS) which can be interconnected in parallel with one another and which can be connected to the monitoring device (AE) via a supply line (L), which has a) an A / D converter (ADC) at least for detecting an exciter voltage (UD) applied to the sensor (DMS) and an associated exciter current (IV), b) a control unit (C), which is connected to the A / D converter (ADC) via a data line (DV) and which has first means (M1), the b1) continuously determining a value (Z *) for the impedance (Z) of the resistive sensor (DMS) from the exciter voltage (UD) detected by the A / D converter (ADC), b2) determine a difference from the currently determined impedance value (Z *) and a predefinable desired impedance value (Zo), and b3) output an error message (FA) if the difference exceeds a predefinable tolerance value (lim) in terms of amount. Monitoring device (AE) according to claim 6, with the A / D converter (ADC) for detecting a voltage applied to the resistive sensor (DMS) Measuring voltage (US) and with the control unit (C) with second means (M2), which determine the ratio of the measuring voltage (US) and excitation voltage (UD) and output proportional to the ratio (K) weight (F *) or mass value , Monitoring device (AE) according to claim 6 or 7, with the resistive sensor (DMS) in a Wheatstone bridge circuit. Monitoring device (AE) according to one of the preceding claims 6 to 8, wherein the resistive sensor (DMS) consists of at least one strain gauge (R1-R4). Monitoring device (AE) according to one of the preceding claims 6 to 9, wherein a plurality of resistive sensors (DMS) are connected in parallel, which can be connected via a supply line (L) to the monitoring device (AE). Industrial scale, in particular for automation and production technology, which has a load cell (WZ) with at least one resistive sensor (DMS), wherein the load cell (WZ) via a supply line (L) to a monitoring device (AE) according to one of the preceding claims 6 to 10 is connected.

Images