Source: https://patents.google.com/patent/US6519546B1/en
Timestamp: 2019-04-21 01:16:14+00:00

Document:
A transmitter in a process control system includes a resistance-based sensor sensing a process variable and providing a sensor output. Self heating circuitry coupled to the sensor provides a self heating signal related to the sensor. Analog-to-digital conversion circuitry coupled to the sensor output provides a digitized sensor output, and transmitter output diagnostic correction circuitry provides an auto corrected output as a function of the self heating signal output or in another embodiment, the transmitter outputs a residual life estimate of the sensor as a function of the self heating index. A novel method of calculating the self heating index is also disclosed, which is applicable to various methods for providing a diagnostic transmitter output.
This is a Continuation-In-Part application of application Ser. No. 09/016,216, filed Jan. 30, 1998 abandoned which is a Continuation-In-Part of application U.S Ser. No. 08/744,980, filed on Nov. 7, 1996 now U.S. Pat. No. 5,828,567.
The present invention relates to transmitters of the type used in the process control industry. More specifically, the invention relates to diagnostics for process control transmitters which include a resistance based temperature sensor.
Process control transmitters are used to monitor process variables in industrial processes. For example, a transmitter might monitor temperature and transmit such information back to a control room. Furthermore, some transmitters are capable of performing the control function directly. In order to monitor a process variable, the transmitter must include a sensor, for example, an RTD which is a resistance based temperature sensor.
As the RTD sensor ages or is subjected to harsh environmental conditions, the accuracy of the sensor tends to degrade. It is possible to compensate for this degradation by periodically recalibrating the transmitter. Typically, this requires an operator to enter the field and perform a calibration process on-site on the transmitter. This is both inconvenient and time consuming for the operator. Further, it is difficult to determine the condition of a sensor, prior to its ultimate failure.
It is also necessary for the sensors to be periodically replaced as they age. However, it is difficult to determine precisely when a replacement is necessary. Therefore, sensors are typically replaced well before their failure or, in some cases, they may fail unexpectedly.
A transmitter in a process control system includes a resistance-based sensor sensing a process variable and providing a sensor output. Self heating circuitry coupled to the sensor provides a self heating signal related to the sensor. Analog-to-digital conversion circuitry coupled to the sensor output provides a digitized sensor output, and transmitter output diagnostic correction circuitry provides an auto corrected output as a function of the self heating signal output or in another embodiment, the transmitter outputs a residual life estimate of the sensor as a function of the self heating index. A novel method of calculating the self heating index is also disclosed, for use in the present invention.
FIG. 1 shows a process control system including a transmitter in accordance with the present invention.
FIG. 2 is a block diagram of a transmitter of the present invention.
FIG. 3 is a simplified block diagram of a transmitter in accordance with one embodiment of the invention.
FIG. 4 is a simplified block diagram in accordance with an embodiment of the present invention.
FIG. 1 is a diagram of process control system 2 including field mounted temperature transmitter 40 and a valve controller 12 coupled electrically to control room 4 over a two wire process control loops 6 and 14, respectively. Transmitter 40, mounted on a manifold and connected to the pipe via a manifold, monitors the temperature of process fluid in process piping 18. However, the present invention applies to any resistance based process variable measurement such as a resistance based pressure measurement or a resistance based pH measurement. Transmitter 40 transmits temperature information to control room 4 over loop 6 by controlling the current flowing through loop 6. For example, the current flowing through loop 6 may be controlled between 4 and 20 mA and properly calibrated to indicate temperature. Additionally or in the alternative, transmitter 40 may transmit digital information related to temperature over loop 6 to control room 4 such as in a HART® or an all digital protocol such as Fieldbus. Transmitter 40 includes circuitry described herein in more detail which provides advanced diagnostics related to temperature sensor operation.
One aspect of the present invention includes a recognition of a close correlation, in some cases linear relationship, of the SH index to the “alpha” and/or R0 of the sensor. As is known, alpha and/or R0 of a sensor is related to sensor calibration and therefore to sensor lifetime. Accordingly, if the SH index is measured, the lifetime of the sensor can be estimated. Furthermore, the sensor output can be corrected in real-time as a function of the amount of degradation (e.g., the difference between a preselected value of the SH index and the true current value of the SH index) . This provides an autocorrection to the transmitter output.
The invention can be practiced in any of a number of places in a process system control system. In particular, the present invention as realized in software and a microprocessor, can reside in a central controller or even a final control element 12 such as a valve, motor or switch as shown in FIG. 1. Furthermore, modern digital protocols such as Fieldbus, Profibus and others allow for the software which practices the present invention to be communicated between elements in a process control system, and also provide for process variables to be sensed in one transmitter and then sent to the software.
FIG. 2 is a simplified block diagram of a temperature transmitter 40 connected to RTD temperature sensor 10 in accordance with the present invention. Transmitter 40 includes terminal block 44, current source 45, multiplexer 46, differential amplifier 48, high accuracy A/D converter 50, microprocessor 52, clock circuit 54, memory 56 and input-output circuit 58.
Terminal block 44 includes terminals 1 through 5 for coupling to, for example, RTD temperature sensor 10. Sensor 10 can be either internal or external to transmitter 40. Sensor 10 includes RTD sensor element 61 having a resistance R1 which varies with changes in the ambient temperature. Leads 16 include four element leads 62, 64, 66 and 68. Lead 62 is connected between sensor element 61 and terminal 4, lead 64 is connected between sensor element 61 and terminal 3, lead 66 is connected between sensor element 61 and terminal 2, and lead 68 is connected between sensor element 61 and terminal 1.
Current source 45 is connected to terminal block 44 and supplies a measurement current Is through terminal 4, sensor element 61, terminal 1, reference resistance RREF, pull-down resistance R2 and ground terminal 72. Sensor element 61 develops a voltage drop across terminals 2 and 3 which is a function of the resistance R1 and thus the temperature of sensor element 61. Reference resistor RREF is connected between terminal 1 and pull-down resistor R2.
Multiplexer 46 is divided into two sections, an active multiplexer having an output connected to the non-inverting input of differential amplifier 48 and a reference multiplexer having an output connected to the inverting input of differential amplifier 48. Microprocessor 52 controls multiplexer 46 to multiplex appropriate sets of analog signals, including signals from terminals 1 through 3, to the non-inverting and inverting inputs of differential amplifier 48. Differential amplifier 48 has an output connected to A/D converter 50. In one embodiment, A/D converter 50 has an accuracy of 17 bits and a conversion rate of 14 samples/second. A/D converter 50 converts the voltage at the output of differential amplifier 48 into a digital value and provides that value to microprocessor 52 for analysis or for communication over process control loop 6 through input-output circuit 58.
Input-output circuit 58, in a preferred embodiment, includes a HART® communication section, a FIELDBUS communication section and a 4-20 mA analog loop section for analog or bi-directional digital communicating over loop 6 according to a selected protocol in a known manner. Other protocols can also be used, for example, a four-wire configuration may be employed in which power is received from a separate source. Loop 6 also provides power to the various components of transmitter 40 through input-output circuit 58. Preferably, transmitter 40 is wholly (completely) powered by the two-wire loop 6.
Memory 56 stores instructions and information for microprocessor 52, which operates at a speed determined by clock circuit 60. Clock circuit 60 includes a real time clock and a precision high speed clock, which are also used to sequence the operation of A/D converter 50. Microprocessor 52 performs several functions, including control of multiplexer 46 and A/D converter 50, control of communications over loop 6, temperature compensation, storage of transmitter configuration parameters and performing sensor diagnostics.
RREF in Ohms, and/or stored in memory 56.
R(t)=Resistance at temperature t, in Ohms.
R0=Resistance at temperature 0, in Ohms.
β=0 for t>0 deg C.
However, both stored lookup tables or the equation 2 must be properly calibrated for a particular RTD temperature sensor. Further, such calibration tends to change over time as the alpha (α) for the sensor drifts. Calibrating an RTD requires an accurate thermometer reference to obtain a number of correct temperature values in order to accurately determine the constants α and δ. Equation 3 and transmitter calibration are discussed in PRT Handbook Bulletin 1042, dated February 1985, published by Rosemount and incorporated by reference into this application.
The SH index is calculated when microprocessor 52 actuates switch 138 to couple current source 140 to sensor 61. Pand R1 of equation 1 are calculated with current ISH from source 140 flowing through sensor 61. Microprocessor 52 determines P2 and R2 due to current Is from source 45. The SH index is calculated using equation 1. If transmitter 40 is completely powered from loop 6, the currents ISH and Is are limited to the current I in loop 6, less any current required to operate circuitry in transmitter 40.
Microprocessor 52 performs diagnostics related to operation of transmitter 40 using the SH index. The following describes a number of embodiments for realizing the diagnostic circuitry in transmitter 40. Such diagnostics include determining sensor health, performing a residual lifetime estimate may be representative of an impending sensor failure, or performing an autocorrection to the temperature measurement.
Tcorrected is the autocorrected temperature.
The relationship between K and the change in SHI may be determined experimentally. Determination of K may be through an equation or, in one preferred embodiment, with a lookup table stored in memory 56 as a function of change in SHI. Similarly, SHI, or change in SHI, can be correlated to alpha (α) and R0, or changes in these constants. Further, it is within the scope of the present invention to correlate SHI or ΔSHI to other constraints in Equation 3.
FIG. 3 is a block diagram 150 illustrating the present invention as it relates to autocorrection of the temperature output as a function of the SH index. Diagram 150 shows operations which would typically be performed by microprocessor 52 in FIG. 2. At block 152, the previous value of the self heating index (SHI1) is obtained, for example, from memory 56. This value may have been stored in memory during manufacture, previously generated by microprocessor 52 or determined and stored when the transmitter was commissioned or even at a preselected time during operation of transmitter 40. At block 154 the current value of the SH index (SHI2) is determined by microprocessor 52. If the rate of change, m is greater than or equal to a maximum allowable rate of change (mMAX), decision block 158 provides an alarm output. In general, a value representative of the difference between SHI2 and SHI1 is assessed at block 156. A preferred method for this differencing function is to calculate the slope over time of the two SHI values. However, other methods of assessing the amount of difference, some as simple as comparing SH2 to a threshold value, can be implemented without block 156. The output may be transmitted, for example, over loop 6 to indicate that the sensor has degradated to such an extent that failure is imminent and replacement is necessary. Other types of diagnostics may also be performed such as those set forth in the parent application U.S. Ser. No. 08/744,980, filed Nov. 7, 1996. The value of mMAX is stored in memory 56 and may be user configurable based upon the accuracy desired for a particular process. The alarming function at block 158 is optional, but preferred to the present invention.
If the alarm condition does not exist, control passes to decision block 160 in which the measured self heating index (SHI2) is compared with the stored self heating index (SHI1). If they are approximately the same, control is passed to block 162 and the temperature is determined. If, on the other hand, there is a difference between the two values, a new value for the ΔSHI in equation 4 is calculated by microprocessor 52 at block 164. Further, other more complex curve fitting techniques can be used to correlate SHI with sensor calibration. Control is passed to block 162 and the new value for ΔSHI in equation 4 is used in determining temperature. The new value for ΔSHI is stored in memory to replace the previous value.
The various functions set forth in FIG. 3 may be performed remotely, in a process control device, in the control room, in a computer located off-site or in a combination of these locations. Generally, the invention can be practiced in any of a number of places in a process system control system. In particular, the present invention as realized in software and a microprocessor, can reside in a central controller or even a final control element such as a valve, motor or switch as shown in FIG. 1. Furthermore, modern digital protocols such as Fieldbus, Profibus and others allow for the software which practices the present invention to be communicated between elements in a process control system, and also provide for process variables to be sensed in one transmitter and then sent to the software.
One embodiment of diagnostic circuitry in the present invention uses empirical models or polynomial curve-fitting which are functions of SH index. For example, a polynomial which is a function of the SH index is used for computing the residual lifetime estimate. The constants and/or the equations may be sent over the two wire loop to transmitter 40. Another diagnostic circuit is implemented with a multi-layer neural network. Although a number of training algorithms can be used to develop a neural network model for different goals, one embodiment includes the known Backpropagation Network (BPN) to develop neural network modules which will capture the nonlinear relationship among a set of input and outputs(s).
Another embodiment of diagnostic circuitry 52 uses a set of if—then rules to reach a conclusion on the status of the temperature sensor RTD 61. The SH index is monitored and its present value is compared to upper and lower boundaries. The upper and lower boundaries are empirically set by testing of many RTD sensors. A decision is made based upon the comparison.
In another aspect of the invention, the rate of change (ROC) of the SH index is correlated with life expectancy of sensor 61. The ROC of the SH index is provided to the diagnostic circuitry implemented in microprocessor 52 which provides an output indicative of expected life, including a warning when the expected remaining sensor life has dropped below a minimum value.
diagnostic circuitry coupled to the digitized self heating signal responsively providing a diagnostic output related to sensor calibration as a function of the digitized self heating signal.
2. The transmitter of claim 1 including a memory storing a set of expected results related to the self heating signal.
3. The transmitter of claim 1 wherein the diagnostic circuitry comprises a neural network.
4. The transmitter of claim 1 wherein the diagnostic circuitry comprises fuzzy logic.
5. The transmitter of claim 1 wherein the diagnostic circuitry provides a residual lifetime estimate output.
6. The transmitter of claim 5 wherein the diagnostic circuitry determines the residual lifetime estimate as a function of rate of change (ROC) of the digitized self heating signal.
7. The transmitter of claim 1 wherein the self heating circuitry includes a current source and voltage measurement circuitry.
8. The transmitter of claim 1 wherein the self heating circuitry determines the SH index as a function of a change in sensor resistance in response to a change in power applied to the sensor.
9. The transmitter of claim 8 wherein the SH index is calculated as (R1-R2)/(P1-P2).
10. The transmitter of claim 1 wherein the output circuitry calibrates the sensor temperature signal in response to the diagnostic output.
11. The transmitter of claim 1 wherein the calibration is a function of the self heating signal.
12. The transmitter of claim 1 wherein the diagnostic output is indicative of sensor life expectancy.
providing a diagnostic output as a function of the SHI.
14. The method of claim 13 wherein obtaining the SHI comprises measuring change in sensor resistance in response to a change in power applied to the sensor.
15. The method of claim 14 wherein the self heating index is calculated as (R1-R2)/(P1-P2).
16. The method of claim 13 including estimating residual life of the sensor based upon a rate of change of the SHI.
17. The method of claim 13 wherein obtaining the SHI includes sequentially injecting at least two different current levels into the sensor and measuring the resultant voltage drop across the sensor.
18. The method of claim 13 including determining sensor life expectancy as a function of the diagnostic output.
19. The method of claim 13 including determining temperature of the sensor as a function of the sensor output and the SHI.
diagnostic circuitry providing a self heating (SH) index output as a function of injected current and the voltage drop across the sensor.
21. The transmitter of claim 20 wherein the diagnostic circuitry provides a life expectancy output as a function of the SH index.
22. The transmitter of claim 20 including temperature measurement circuitry providing an output related to sensor temperature as a function of sensor resistance and the SH index.
23. The transmitter of claim 20 wherein the SH index is determined as a function of a change in sensor resistance in response to a change in power applied to the sensor.
24. The transmitter of claim 21 wherein the SH index is calculated as (R1-R2)/(P1-P2).
output circuitry coupled to the process control loop for transmitting the measured temperature on the loop.
26. The temperature transmitter of claim 25 wherein a constant R0 of the temperature sensor changes as a function of change in the self heating signal.
27. The temperature transmitter of claim 25 wherein a constant alpha (α) of the temperature sensor changes as a function of change in the self heating signal.
28. The temperature transmitter of claim 25 wherein the measured temperature is a function of the sensor signal times a constant K.
29. The temperature transmitter of claim 28 wherein the measured temperature is linearly related to K, where K is a function of the self heating index.
30. The temperature transmitter of claim 28 including a lookup table stored in a memory, the lookup table providing K as a function of the self heating signal.
31. The temperature transmitter of claim 25 including diagnostic circuitry coupled to the digitized self heating signal responsively providing a diagnostic output related to sensor calibration as a function of the digitized self heating signal.
diagnostic circuitry providing a self heating (SH) index output as a function of injected current and the voltage drop across the sensor, the self heating index defined as a change in sensor resistance for a given change in power input to the sensor.
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