RU2323418C1 - Identification of type of flowmeter - Google Patents

Abstract

FIELD: invention refers to measuring technique.

SUBSTANCE: monitoring system of Coriolis's flowmeter has interface of communication with one or more flowmeters and reception of values of calibration of measuring instrument for one or more flowmeters. Monitoring system includes also processing system connected with interface of communication and assigned for reception of values of calibration of measuring instrument from interface of communication and comparison of values of calibration of measuring instrument with known values of calibration of measuring instrument to define type of flowmeter. Known values of calibration of measuring instrument contain structure of data which connects type of flowmeter with set of values of calibration of measuring instrument. Values of calibration of measuring instrument contain calibration coefficient of consumption. Processing system is additionally configured for storage of definite type of flowmeter in structure of data together with identificator of flowmeter.

EFFECT: ensures simple and exact definition of type of flowmeter not demanding additional actions from side of user and additional apparatus means in flowmeter.

29 cl, 3 dwg

Description

Technical field

The present invention relates to the identification of a flowmeter type, and more particularly to the identification of a flowmeter type using flow meter calibration values.

BACKGROUND

Flowmeters are used to measure the specific mass flow rate of moving fluids. There are many types of flow meters that combine various applications and fluid materials. For example, there may be different types / models of flow meters for different linear sizes of flow tubes, tube materials, pressure ratings, temperature ratings, accuracy ratings, etc. Each type of flowmeter may have unique characteristics that the flow measurement system must consider in order to ensure optimal operating conditions. For example, some types of flowmeters may require devices with a flow tube for vibration at specific working volume levels. Or some types of flow meters require special compensation algorithms.

Flowmeter electronic circuits typically include stored meter calibration values. The flowmeter uses these meter calibration values to accurately measure specific mass flow rate and density. Meter calibration values may contain calibration values derived from measurements during tests, for example, at the factory.

Therefore, each flowmeter can have unique calibration values.

One type of flowmeter is a Coriolis flowmeter. It is known to use Coriolis mass flowmeters to measure mass flow rate and other information about materials flowing through a pipeline (see, for example, US Pat. No. 4,491,025, 1985 and No. 3,1450, 1982). These flow meters have one or more flow tubes of various configurations. Each pipeline configuration can be considered as having a set of natural vibrations, including, for example, simple bending, torsional, radial and coupled vibrations. In a typical application of a Coriolis mass flowmeter, a pipeline configuration is excited in one or more vibration modes as a substance flows through the pipeline, and the movement of the pipeline is measured at points spaced along the pipeline. The modes of oscillation of the systems filled with matter are partly determined by the combined mass of the flow tubes and the material inside the flow tubes. When there is no material flowing through the flowmeter, all points along the flow tubes oscillate with the same phase. When a substance begins to flow through the flow tube, Coriolis accelerations cause each point along the flow tube to have a different phase relative to other points along the flow tube. The phase on the input side of the flow tube is behind the setpoint signal, while the phase on the output side is ahead of the setpoint signal. The sensors are located at different points on the flow tube to generate sinusoidal signals representing the movement of the flow tube at different points. The phase difference of the signals received from the sensors is calculated in units of time. The phase difference between the sensor signals is proportional to the specific mass flow rate of the substance flowing through the flow tube or flow tubes.

The specific mass flow rate of a substance is determined by multiplying the phase difference by a calibration flow coefficient (FCF). Before installing a flowmeter in an FCF pipe, it is determined through a calibration flow. During calibration operations, fluid is passed through the flow tube at a predetermined flow rate, and the relationship between the phase difference and flow rate (i.e., FCF) is calculated. The flow meter subsequently determines the flow by multiplying the FCF by the phase difference of the two load cell signals. In addition, other calibration factors can be considered when determining the flow rate.

In many applications of flow meters, there is a network of flow meters that includes many individual flow meters operating within a communication network. The network, as a rule, includes a flowmeter control system that collects the measured flow data and controls and coordinates the actions of various flowmeters. A flowmeter network can include flowmeters of various sizes, models, model years, as well as electronic circuits and software versions. In such an environment, it is desirable that the type of flowmeter be easily and automatically identified so that maintenance and modernization procedures can be carried out rationally and properly.

When electronic flowmeters were first developed, identifying and tracking the type of flowmeter was not a problem. This was due to the relatively small number of flowmeter manufacturers and the small number of flowmeter models. As a result, manual tracking and recording of flowmeter types was easy. However, it is impossible to design a flowmeter without taking into account the unique characteristics in special cases of use, along with ensuring low costs, higher performance, less footprint and other aspects required of the flowmeter. As a result, the number of types of flowmeters has increased to suit special and wide needs.

One of the known approaches requires the user to introduce the model / type of sensor into the flowmeter control device, for example, entering a code or identifier. This approach is acceptable if the person entering is well aware of the flow meters and the types of flow meters. However, this known approach has drawbacks because it is based on the fact that the person entering it should at least be familiar with the known types of flow meters, should know how to enter data into the transmitter or control device, and also ensure a complete, error-free and precise entry of code or identifier.

Another known approach is for the flowmeter to contain a memory device. The memory stores data on the type of flowmeter in the form of a readable code or identifier. A remote flowmeter monitoring system may request memory to obtain a code or type identifier for the flowmeter. However, this known approach also has disadvantages. The presence of a memory device significantly increases the cost of the flowmeter. In addition, a memory device, such as a solid state memory, is a relatively fragile device that is unsuitable for inclusion in a high temperature and high vibration meter.

Another well-known approach is to include a resistor in the flowmeter, while the resistor generates a relatively unique electrical voltage / current response signal that is read remotely. A resistor is an inexpensive and robust device that can be easily integrated into a flowmeter. However, this approach also has disadvantages. The increasing number of flowmeter types makes it necessary to use smaller and smaller resistance ranges to define each flowmeter model. This leads to uncertainties when the tolerance of the resistance is critical. In addition, a global identification of the type of flowmeter would require coordination between manufacturers of flowmeters.

Another approach is to excite the initial vibrations of the flowmeter in question and measure the resulting oscillation frequency of the flow tube. The resulting oscillation frequency is then compared with the type of flowmeter. However, this approach also has disadvantages. The vibration test must be carried out properly and the flow meter must be in the appropriate test conditions. In addition, the verification may result in measured response frequencies that do not fully indicate the type of flowmeter. Changes in the permissible deviations of the flowmeter, together with changes in environmental conditions, may result in an incorrect determination of the type of flowmeter.

SUMMARY OF THE INVENTION

The technical task of the present invention is to remedy these disadvantages in the art by creating a system and method for identifying the type of flow meter.

According to an embodiment of the invention, a flowmeter monitoring system is provided. The flow meter monitoring system comprises a communication interface for communicating with one or more flow meters and receiving meter calibration values for the flow meter of one or more flow meters. The flow meter monitoring system further comprises a processing system associated with the communication interface for receiving meter calibration values from the communication interface and comparing the meter calibration values with known meter calibration values to determine the type of meter.

According to an embodiment of the invention, there is provided a method for identifying a type of flow meter that comprises receiving meter calibration values for a meter and comparing the meter calibration values with known meter calibration values to determine the type of meter.

According to an embodiment of the invention, there is provided a software product for determining the type of flowmeter. The software product contains control software for instructing the processing system to accept meter calibration values for the flow meter and match the meter calibration values with known meter calibration values to determine the type of meter. The software product also contains a storage system that provides storage of management software.

The following are aspects of the invention. In one aspect of the invention, the meter calibration values include a calibration flow coefficient (FCF) and a harmonic frequency value (K1).

In another aspect of the invention, known meter calibration values comprise a data structure that associates a particular type of flowmeter with a separate set of meter calibration values.

In yet another aspect of the invention, a particular type of flowmeter is stored in a data structure along with a flowmeter identifier.

In yet another aspect of the invention, meter calibration values for a flowmeter are received from the flowmeter.

In yet another aspect of the invention, meter calibration values for a flow meter are received through a user interface.

In yet another aspect of the invention, the flowmeter monitoring system comprises a flowmeter element.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is further explained in the description of the preferred embodiments of the invention with reference to the accompanying drawings, in which:

figure 1 depicts a monitoring system of a flow meter according to the invention;

figure 2 is a diagram of the relationship between some types of flow meters and the values of FCF and K1 according to the invention;

3 is a flowchart of a method for identifying a type of flowmeter according to the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

Figure 1-3 presents separate examples to explain how to make and use the best variant embodiment of the invention. The examples below are presented with an explanation of two embodiments of the invention. However, more than two embodiments may be used. Those skilled in the art will appreciate that the features described below can be combined in various ways to form numerous variations of the invention. As a result, the invention is not limited to the individual examples described below, but only by the claims and their equivalents.

1 shows a flow meter monitoring system 100 according to an embodiment of the invention. The flowmeter monitoring system 100 comprises a flowmeter, a flowmeter transmitter, a remote terminal, etc. The flow meter monitoring system 100 may collect measured flow data and control and coordinate the operations of one or more different flow meters. In some embodiments, a flowmeter monitoring system 100 may communicate with one or more flowmeters 150 through a network 170.

The flow meter 150 may comprise, for example, a Coriolis flow meter. The flow meter 150 may include stored meter calibration values, such as a calibration flow coefficient 151 (FCF) and a harmonic frequency value (K1) 152. FCF reflects the geometry of the flow tube of a separate flowmeter device. FCF can take into account the deviations in the dimensions of the flow tube device during manufacture and can also take into account deviations in the response vibrational signal, due to the variation in the material properties of the flow tube. The K1 value represents the harmonic frequency of the flow tube device as measured with air in the flow tube device and at a calibration temperature of 0 ° Celsius. The value of K1 is usually presented in units of frequency or in units of time (i.e., periods of oscillation). Other meter calibration values (not shown) may include, but are not limited to, a K2 value (the same as K1, but for water in the flowmeter device), a K3 value that affects density density, temperature calibration value, etc. Other meter calibration values are contemplated and included within the scope of the invention and claims.

The flowmeter monitoring system 100 in one embodiment includes a communication interface 101 and a processing system 102 and may include a user interface 130. The flowmeter monitoring system 100 receives the meter calibration values for the flow meter 150. The flow meter monitoring system 100 uses the meter calibration values to determine the type flowmeter 150.

In an alternative embodiment, the flow meter monitoring system 100 comprises a flow meter element, i.e. flowmeter monitoring system 100 comprises a portion of flowmeter 150. Therefore, flowmeter 150 may use meter calibration values to determine its own type of flowmeter. In addition, flowmeter 150 may receive meter calibration values from other flowmeters and identify meter types.

The type of flow meter is dictated by factors including: the manufacturer, the degree of accuracy of the flow tube device, the nominal pressure, the nominal temperature, the material or materials used to form the flow tube device, and the linear dimensions of the pipeline forming the flow meter. Each of these flowmeter characteristics can influence or control the determination of the type of flowmeter (FIG. 2).

Preferably, the flow meter monitoring system 100 may read the meter calibration values remotely, for example, by receiving meter calibration values from the flow meter 150 via the communication interface 101.

Values can be read over a bus or communication line or can be read over a wireless communication line. Values can be read at any time. Alternatively, meter calibration values may be input directly to the flowmeter monitoring system 100 by a user via user interface 130. In another alternative, meter calibration values may be obtained from other remote devices via communication interface 101.

The meter calibration values are used in the electronic circuits of the flow meter 150 to calibrate mass flow measurements. Meter calibration values are usually obtained from factory tests. Meter calibration values are usually stored in meter electronic circuits before the meter is shipped from the factory. In addition, meter calibration values can be programmed or reprogrammed in the meter's electronic circuitry by the user. Advantageously, if the flow meter 150 in question is reconfigured, the values can be reprogrammed so that the flow meter 150 in question can still be identified according to the invention. This programming is usually facilitated by using a label attached to the flowmeter, with the factory calibrated meter calibration values stamped, stamped, or printed on the label. Therefore, if required, the user can reprogram the flowmeter with appropriate calibration information, for example, in the event of a power failure, memory loss, reconfiguration, etc.

The communication interface 101 is configured to communicate with the flowmeter 150 and other flowmeters, and can also be used to communicate with other devices in the flowmeter network. The communication interface 101 may receive meter calibration values, for example, from a flow meter 150. Alternatively, the communication interface 101 may receive meter calibration values from a remote terminal or device.

Communication interface 101 may comprise any type of communication device. In one embodiment, the communication interface 101 comprises a modem, network card, etc., configured to support communication over network 170. Network 170 may include a wired network, including a dial-up network or a digital packet network. In another embodiment, the communication interface 101, for example, comprises a wireless communication device, such as a radio or optical receiver or transceiver.

The processing system 102 conducts operations of the flow meter monitoring system 100. The processing system 102 is in communication with the communication interface 101 and is configured to receive meter calibration values from the communication interface 101 and to compare the meter calibration values with the known meter calibration values to determine the type of flow meter. Processing system 102 may comprise a general purpose computer, microprocessor system, logic circuit, or some other general purpose or custom processing device. Processing system 102 may be distributed among multiple processing devices. The processing system 102 may include any kind of integrated or autonomous electronic storage medium, for example, a storage system 103.

The storage system 103 may include an FCF storage device 110, a K1 storage device 112, known meter calibration values 114, and a flow meter type storage device 116. FCF memory 110 and K1 memory 112 may store the received FCF and K1 values to identify the type of flowmeter. Known meter calibration values 114 may comprise a data structure that stores known values used to identify the type of flow meter (disclosed below). For example, known meter calibration values 114 may include a data table. However, it should be understood that other data structures can be used to store and map meter calibration values. The flowmeter monitoring system 100 may store a specific identification of the type of flowmeter in a flowmeter type memory 116.

In one embodiment, the known meter calibration values are stored in correspondence table 114. Correspondence table 114 includes numerous meter type entries. The meter type record in the correspondence table 114 includes a set of known meter calibration values and a corresponding meter type for a set of known meter calibration values. Therefore, after entering a specific set of meter calibration values, the correspondence table 114 displays a unique type of flow meter corresponding to a specific set of meter calibration values.

Figure 2 presents a diagram of the relationship between some types of flow meters and the values of FCF and K1. It should be noted that not all types of flow meters are shown in the diagram. From the diagram it follows that the values of FCF and K1 for each type of flowmeter presented are tightly grouped. Therefore, by comparing the calibration values of the meter of the flowmeter in question with known parameters and groups, the type of flowmeter can be determined.

FIG. 3 is a flowchart 300 of a method for identifying a type of flowmeter according to an embodiment of the invention. A method for determining the type of flowmeter can be performed by the flowmeter monitoring system 100 and can be implemented in a software product. The software product may run in the flowmeter monitoring system 100. At step 301, the meter calibration values for the flow meter to be identified are received. As discussed previously, meter calibration values may include FCF and K1. Meter calibration values may be simultaneously or in advance received from the flow meter 150 in question, may be simultaneously or in advance received from the user through a user interface, or may be simultaneously or in advance received from a remote terminal.

At step 302, the received meter calibration values are correlated with the known meter calibration values, which essentially represent various types of flow meters. Correlatedly can be performed by comparing the calibration values of the meter of the considered flow meter 150 with the known calibration values of the meter. Mapping can be done by using a data structure, such as a data table.

At optional step 303, a specific type of flowmeter is stored. A certain type of flowmeter can be stored in the data structure, along with the identifier of the flowmeter in question 150. The flowmeter identifier can be any element from the group consisting of the network address, flowmeter number, serial number of the flowmeter, assigned flowmeter number, etc., which is used to identifying the flowmeter 150 in question. The type of flowmeter may comprise, for example, the type of Coriolis flowmeter.

The flow meter monitoring system 100 (and method) can advantageously determine the type of flow meter by comparing the FCF and K1 values with known types of flow meters. These two pieces of information apply to all Coriolis flowmeters and are sufficient to accurately characterize the Coriolis flowmeter. The invention, therefore, can determine the characteristics of the flow meter, including, for example, the manufacturer, the linear size of the flow tube device, the material (s) of the flow tube device, the nominal pressure of the flow tube device, the nominal temperature of the flow tube device, and the degree of accuracy of the flow tube device.

The system and method for identifying the type of flowmeter according to the invention differs from the prior art in that the calibration values of the meter are used to determine the type of flowmeter. The user does not need to enter any additional codes or identifiers. The user does not have to perform any additional steps in order to identify the type of flowmeter.

The determination of the type of flowmeter according to the invention can be implemented according to any of the embodiments in order to, if required, obtain some advantages. Flowmeter type identification provides a low cost for determining flowmeter type. No additional hardware is required in the flowmeter or in the flowmeter control system, and the invention can be implemented by additional software procedures. Identification of the type of flowmeter provides an accurate and reliable determination of the type of flowmeter without introducing additional problems. Identification of the type of flow meter provides identification that does not require additional actions or operations by the user or system operator. Identification of the type of flow meter provides identification of the type of flow meter that uses information that is inherent in the flowmeter or within the system or network of flowmeters. Moreover, the identification of the type of flow meter provides identification of the type of flow meter, which can inform the user about an error in entering the values of FCF or K1, if a certain type of flow meter is different from the expected type of flow meter.

Claims (29)

1. A flowmeter monitoring system (100) comprising a communication interface (101) for communicating with one or more flow meters and receiving meter calibration values for one or more flow meters, and a processing system (102) associated with the communication interface (101) for receiving meter calibration values from the interface ( 101) communication and comparison of the calibration values of the meter with the known values (114) of the calibration of the meter in order to determine the type of flow meter. 2. System (100) according to claim 1, characterized in that the meter calibration values comprise a calibration flow coefficient (FCF). 3. The system (100) according to claim 1, characterized in that the calibration values of the meter contain the frequency value (K1) of the harmonic. 4. System (100) according to claim 1, characterized in that the known meter calibration values (114) contain a data structure that associates the type of flowmeter with a set of meter calibration values. 5. System (100) according to claim 4, characterized in that the processing system (102) is further configured to store a certain type of flowmeter in the data structure along with the flowmeter identifier. 6. System (100) according to claim 1, characterized in that the meter calibration values for the flow meter are received from the flow meter. 7. System (100) according to claim 1, characterized in that the calibration values of the meter for the flow meter are received through the user interface (130). 8. System (100) according to claim 1, characterized in that the type of flowmeter comprises a Coriolis flowmeter. 9. System (100) according to claim 1, characterized in that it comprises a flowmeter element, which is a flow tube. 10. The method of determining the type of flow meter, which consists in accepting the calibration values of the meter for the flow meter and comparing the calibration values of the meter with the known calibration values of the meter (114) in order to determine the type of flow meter. 11. The method according to claim 10, characterized in that the calibration values of the meter contain a calibration coefficient of flow (FCF). 12. The method according to claim 10, characterized in that the calibration values of the meter contain the frequency value (K1) of the harmonic. 13. The method according to claim 10, characterized in that the known values (114) of the calibration of the meter contain a data structure that associates the type of flowmeter with a set of calibration values of the meter. 14. The method according to claim 10, characterized in that it further stores a certain type of flowmeter in the data structure along with the flowmeter identifier. 15. The method according to claim 10, characterized in that the calibration values of the meter for the flow meter is taken from the flow meter. 16. The method according to claim 10, characterized in that the calibration values of the meter for the flow meter are received through the user interface (130). 17. The method according to claim 10, characterized in that the correlation is carried out in the flowmeter monitoring system (100). 18. The method according to claim 10, characterized in that the type of flowmeter comprises a Coriolis flowmeter. 19. The method according to 17, characterized in that the monitoring system of the flowmeter contains a flowmeter element, which is a flow tube. 20. A storage system (103) for a flowmeter monitoring system configured to store control software for instructing the processing system to accept meter calibration values for a flow meter and to compare meter calibration values with known meter calibration values (114) in order to determine the type flow meter. 21. The storage system according to claim 20, characterized in that the meter calibration values contain a calibration flow coefficient (FCF). 22. The storage system according to claim 20, characterized in that the calibration values of the meter contain the frequency value (K1) of the harmonic. 23. The storage system according to claim 20, characterized in that the known meter calibration values (114) comprise a data structure that associates the type of flowmeter with a set of meter calibration values. 24. The storage system according to claim 20, characterized in that it further comprises a storage device for storing a certain type of flowmeter in the data structure along with the identifier of the flowmeter. 25. The storage system according to claim 20, characterized in that the calibration values of the meter for the flow meter are received from the flow meter. 26. The storage system according to claim 20, characterized in that the calibration values of the meter for the flow meter are received through the user interface (130). 27. The storage system according to claim 20, characterized in that it contains the correlation occurring in the flowmeter monitoring system (100). 28. The storage system according to claim 20, characterized in that the type of flowmeter contains a Coriolis flowmeter. 29. The storage system according to claim 20, characterized in that the monitoring system of the flowmeter contains a flowmeter element, which is a flow tube.

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