JP6500585B2 - Measurement system and method - Google Patents

Description

  The present invention relates to measurement systems and methods.

  In plants and factories, steam is widely used for heating in the production process, heating / humidification in air conditioning, and various other applications. In order to efficiently supply steam used in such a wide range of applications, for example, a boiler that produces steam is centrally installed in a plant or the like, and the steam generated by this boiler is connected by piping extending from the boiler A steam supply system is provided which leads to each part (site requiring steam). In a plant or the like equipped with such a steam supply system, it is essential to measure the flow rate (or flow rate) and the degree of moisture (or dryness) of steam in order to "visualize" energy.

  The following patent documents 1 to 3 disclose conventional techniques for measuring the flow rate of steam. Specifically, Patent Document 1 below discloses a conventional technique in which an orifice plate is installed in a duct through which steam to be measured flows, and the flow rate of steam is measured from the differential pressure at the upstream position and downstream position of the orifice plate. ing. The following Patent Document 2 discloses a conventional technique for measuring the flow rate of steam using an ultrasonic flowmeter, and the following Patent Document 3 measures the flow rate of steam using a vortex flowmeter. Technology is disclosed.

  Moreover, although the following patent documents 4 do not measure the flow of vapor, the prior art which measures the flow of the fluid which flows through the inside of piping is indicated. Specifically, in Patent Document 4 below, the temperature change of the fluid flowing in the piping is detected by two temperature sensors installed upstream and downstream of the piping surface, and the fluid flowing in the piping based on the time difference at that time The prior art for measuring the flow rate of

JP, 2010-276381, A JP, 2013-185914, A JP 2012-185100 A JP, 2010-261826, A

  By the way, the prior art disclosed in Patent Document 4 described above can measure the flow rate of the fluid flowing in the pipe using the measurement result of the temperature sensor attached to the pipe surface without processing the pipe and the like. It is possible. Therefore, if this prior art can be applied to the flow rate measurement of steam, the flow rate and flow rate of steam can be easily measured at low cost as compared with the prior art disclosed in Patent Documents 1 to 3 described above. It is considered possible.

  However, even when trying to apply the prior art disclosed in Patent Document 4 described above to the measurement of steam, the flow velocity of steam can not be accurately measured. This is because steam has a significantly lower thermal conductivity than water, so the heat of the steam flowing in the pipe is not transmitted to the pipe surface, and the temperature sensor can not detect the temperature of the pipe surface well. Therefore, a new technology capable of accurately measuring the flow velocity of the steam flowing inside the pipe from the outside of the pipe has been desired.

  The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a measurement system and method capable of accurately measuring at least one of the flow velocity and flow rate of steam flowing in the pipe from the outside of the pipe. Do.

In order to solve the above-mentioned subject, in a measuring system (1) which measures at least one of flow velocity and flow rate of steam which circulates through the inside of piping (P), a measuring system of the present invention A heat exchanger (12) for exchanging, and a first control unit for controlling a heat exchange amount of the heat exchanger based on a temperature change of one point in a pipe axial direction of the pipe caused by heat exchange of the heat exchanger ( 18), the first temperature measuring unit (14, 15) for measuring the temperature of one point or a plurality of points of the surface in the tube axis direction of the pipe, and the steam based on the measurement result of the first temperature measuring unit And calculating means for calculating at least one of flow velocity and flow velocity.
In the measurement system of the present invention, the heat exchanger is a heating device, and the first control unit controls the power supplied to the heating device.
Moreover, the measuring system of the present invention is characterized in that the heating device is a ring-shaped heater.
Further, the measurement system according to the present invention is characterized in that the first control unit performs control to gradually increase the power supplied to the heating device when the temperature change is equal to or less than a preset threshold. And
Further, in the measurement system of the present invention, the first control unit associates the temperature change with the power to be supplied to the heating device, and corresponds information prepared for each of the temperature and pressure of the steam ( And control the power supplied to the heating device with reference to the correspondence information.
Further, in the measurement system of the present invention, a preheating unit (11) attached to an outer peripheral surface of the pipe upstream of the predetermined part, and an outer periphery of the pipe between the preheating part and the predetermined part A second temperature measuring unit (13) attached to the surface and a temperature measured by the second temperature measuring unit, and the second control unit controls the preheating unit so that all the moisture of the vapor evaporates. And a controller (17).
Further, the measurement system of the present invention is characterized in that the second temperature measurement unit is attached downstream of the preliminary heating unit and in the vicinity of the preliminary heating unit.
Further, the measurement system of the present invention is characterized in that the second temperature measurement unit is attached to the bottom of the outer peripheral surface of the pipe.
Further, the measurement system of the present invention is characterized in that the second control unit controls the preheating unit such that the temperature measured by the second temperature measurement unit becomes constant.
The measuring method of the present invention is a measuring method of measuring at least one of the flow velocity and flow rate of steam flowing in the pipe (P), and the first step of exchanging heat with a predetermined portion of the surface of the pipe; A second step of controlling a heat exchange amount of the heat exchange based on a temperature change of one point in the pipe axial direction of the pipe caused by the heat exchange performed in the first step; and one point of the surface in the pipe axial direction of the pipe Alternatively, it is characterized by comprising a third step of measuring temperatures of a plurality of points, and a fourth step of calculating at least one of the flow velocity and the flow rate of the steam based on the measurement result of the third step.

  According to the present invention, heat exchange is performed with a predetermined portion of the surface of the pipe, and the heat exchange amount of the heat exchanger is controlled based on the temperature change at one or more points in the pipe axial direction of the surface of the pipe subjected to heat exchange. The temperature of one point or a plurality of points on the surface in the axial direction of the pipe is measured, and at least one of the flow velocity and the flow rate of the steam is calculated based on the measurement result of the first temperature measurement unit. For this reason, there is an effect that it is possible to accurately measure at least one of the flow velocity and the flow rate of the steam flowing in the pipe from the outside of the pipe.

It is a figure which shows the principal part structure of the measurement system by 1st Embodiment of this invention. It is sectional drawing which shows the concrete structure of the temperature measurement part of the measurement system by 1st Embodiment of this invention. It is a block diagram which shows the principal part structure of the data processing apparatus with which the measurement system by 1st Embodiment of this invention is provided. It is a figure which shows an example of the temperature distribution of the surface of piping in the pipe-axis direction of piping formed in 1st Embodiment of this invention. It is a figure which shows the evaluation result of the measurement error in 1st Embodiment of this invention. It is a figure which shows the table used with the measurement system by 2nd Embodiment of this invention.

  Hereinafter, a measurement system and method according to an embodiment of the present invention will be described in detail with reference to the drawings.

First Embodiment
FIG. 1 is a view showing the main configuration of a measurement system according to a first embodiment of the present invention. As shown in FIG. 1, the measurement system 1 of this embodiment includes a preheater 11 (preheating unit), a measurement heater 12 (heat exchanger, heating device, heater), a temperature measurement unit 13 (second temperature measurement unit), Temperature measurement unit 14 (first temperature measurement unit), temperature measurement unit 15 (first temperature measurement unit), pressure gauge 16, preheater control device 17 (second control unit), heater power supply 18 (first control unit), data A collection device 19 and a data processing device 20 (calculation unit) are provided, and the flow velocity of the thermal fluid (for example, steam) flowing in the pipe P disposed between the steam generation device E1 and the load facility E2 is measured. Do.

  Here, the steam generating device E1 is, for example, a boiler, and generates steam by heat obtained by burning an externally supplied fuel. In the present embodiment, it is assumed that the steam generated by the steam generation device E1 is steam, in order to facilitate understanding. The load facility E2 is a facility in which the heat of the steam or the steam generated by the steam generating device E1 and sent through the pipe P is used. The steam discharged from the load facility E2 is collected as a drain, collected in a return water tank (not shown), and then resupplied to the steam generating device E1. Further, as the pipe P, carbon steel pipe for pressure pipe (STPG) or stainless steel pipe (SUS) can be used.

  The preheater 11 is attached to the outer peripheral surface of the pipe P on the upstream side of the measurement heater 12 and heats the pipe P on the upstream side of the measurement heater 12. The preheater 11 is provided to preheat the vapor generated by the vapor generation device E1 before the vapor is input to the measurement heater 12. The reason for providing such a preheater 11 is to make it possible to measure the flow velocity with high accuracy even if the steam has a high degree of moisture by evaporating the moisture contained in the steam in advance. That is, if the steam contains moisture, when the steam containing the moisture reaches the measurement heater 12, the heat of the measurement heater 12 is taken away as the heat of vaporization of the moisture, and as a result As the temperature of the pipe P is lowered, it affects the measurement of the flow velocity. A preheater 11 is provided to eliminate such an influence.

  The preheater 11 is, for example, an electric heater, and is wound around the outer peripheral surface of the pipe P at a constant pitch so as to heat the pipe P uniformly. Here, the length by which the preheater 11 is wound (the length in the pipe axis direction of the pipe P) is, for example, about 1 to several meters. As described above, since the preheater 11 is provided to evaporate the moisture contained in the steam flowing in the pipe P, the length necessary to evaporate the moisture is secured. The preheater 11 may be a ring-shaped heater (for example, a ring-shaped ceramic heater). If the ceramic heater is divided into two parts of a semicircle, mounting on the pipe P can be easily performed.

  The measurement heater 12 is attached to the outer peripheral surface of the pipe P on the downstream side of the preheater 11 and heats the pipe P on the downstream side of the preheater 11. Like the preheater 11, the measurement heater 12 is, for example, an electric heater, and is wound around the outer peripheral surface of the pipe P at a constant pitch so as to heat the pipe P uniformly. Here, the length (the length in the pipe axis direction of the pipe P) in which the measurement heater 12 is wound is, for example, about 1 to several centimeters, and is shorter than the length in which the preheater 11 is wound. It is set to. This is because it is sufficient if the temperature distribution required to measure the flow velocity of the steam flowing in the pipe P can be formed by the measurement heater 12. The measurement heater 12 may also be a ring-shaped heater (for example, a ring-shaped ceramic heater) as in the pre-heater 11.

  The temperature measurement unit 13 is attached to the outer peripheral surface of the pipe P between the preheater 11 and the measurement heater 12 and measures the surface temperature of the pipe P. Specifically, the temperature measurement unit 13 is attached downstream of the preheater 11 and in the vicinity of the preheater 11. For example, the temperature measuring unit 13 is attached at a position about 10 centimeters downstream from the end (end on the downstream side) of the preheater 11. The reason for attaching the temperature measurement unit 13 at such a position is to effectively evaporate the moisture contained in the steam flowing in the pipe P.

  Moreover, the temperature measurement part 13 is attached to the bottom part in the outer peripheral surface of the piping P at the said position at least. Such attachment is also for the purpose of effectively evaporating the moisture contained in the steam flowing in the piping P. For example, when the temperature measurement unit 13 is attached only to the side portion of the outer peripheral surface of the pipe P, the steam is cooled, and the temperature drop due to water droplets generated at the bottom of the inner peripheral surface of the pipe P is measured late. In some cases, the moisture contained in the steam flowing in the pipe P can not be effectively evaporated.

  The temperature measurement unit 14 is attached to the outer peripheral surface of the pipe P on the upstream side of the measurement heater 12 and on the downstream side of the temperature measurement unit 13 and measures the surface temperature of the pipe P. The temperature measurement unit 15 is attached to the outer peripheral surface of the pipe P on the downstream side of the measurement heater 12 and measures the surface temperature of the pipe P. In addition, the temperature distribution of the surface of the pipe P in the pipe axis direction of the pipe P can be obtained from the measurement results of the temperature measuring units 14 and 15.

  FIG. 2 is a cross-sectional view showing a specific configuration of the temperature measurement unit of the measurement system according to the first embodiment of the present invention. 2 (a) is a cross-sectional view of the pipe P in the direction along the pipe axis direction, and FIG. 2 (b) is a cross-sectional view of the pipe P in the direction orthogonal to the pipe axis direction (FIG. 2 (a) (A-A line cross section arrow view). As shown in FIG. 2, the temperature measurement unit 14 includes a plurality of sensor groups (12 sensor groups in the example shown in FIG. 2) arranged along the axial direction of the pipe P on the upstream side of the measurement heater 12. ). Each sensor group provided in the temperature measurement unit 14 includes four temperature sensors 14 a (for example, thermocouples) arranged so as to differ in position by 90 degrees in the circumferential direction of the outer peripheral surface of the pipe P.

  Further, as shown in FIG. 2, the sensor group provided in the temperature measurement unit 14 is arranged such that the distance in the tube axis direction becomes narrower as it is closer to the measurement heater 12. This is because the temperature distribution on the surface of the pipe P in the axial direction of the pipe P is taken into consideration. That is, the temperature distribution on the surface of the pipe P shows a characteristic that the temperature is high in the vicinity of the measurement heater 12, but the temperature is rapidly lowered as it is separated from the vicinity of the measurement heater 12. According to such characteristics, in the vicinity of the measurement heater 12, the sensor group provided in the temperature measurement unit 14 is disposed so as to be dense.

  The sensor group provided in the temperature measurement unit 14 is arranged such that, for example, the distance between adjacent sensors gradually increases as the distance from the measurement heater 12 increases. For example, the sensor group provided in the temperature measurement unit 14 has a distance of 4 mm, 8 mm, 12.5 mm, 17.5 mm, 32.5 mm, 47.5 mm from the end (the end on the upstream side) of the measurement heater 12 , 62.5 mm, 77.5 mm, 107.5 mm, 137.5 mm, 167.5 mm, and 197.5 mm.

  The temperature measurement unit 15 includes a plurality of sensor groups (12 sensor groups in the example shown in FIG. 2) arranged in the direction of the pipe axis of the pipe P on the downstream side of the measurement heater 12. The respective sensor groups provided in the temperature measurement unit 15 are arranged so as to differ in position by 90 degrees in the circumferential direction of the outer peripheral surface of the pipe P, similarly to the respective sensor groups provided in the temperature measurement unit 14 Provided with two temperature sensors 15a (for example, thermocouples).

  Further, as shown in FIG. 2, in the sensor group provided in the temperature measurement unit 15, the distance in the tube axis direction is narrower as it is closer to the measurement heater 12 for the same reason as the sensor group provided in the temperature measurement unit 14. It is arranged as. The sensor group provided in the temperature measurement unit 15 has, for example, a distance of 4 mm, 8 mm, 12 from the end (end on the downstream side) of the measurement heater 12 as in the sensor group provided in the temperature measurement unit 14. .5 mm, 17.5 mm, 32.5 mm, 47.5 mm, 62.5 mm, 77.5 mm, 107.5 mm, 137.5 mm, 167.5 mm, and 197.5 mm.

  A plurality of temperature sensors 14a are provided in each of the sensor groups of the temperature measurement unit 14, and a plurality of temperature sensors 15a are provided in each of the sensor groups of the temperature measurement unit 15 because the average value of the plurality of temperature sensors 14a is a measured value This is for obtaining an average value of the plurality of temperature sensors 15a as a measurement value as well as obtaining. By obtaining the average value as the measurement value as described above, highly reliable measurement results can be obtained. Note that, as shown in FIG. 2, at least a part of the surface of the pipe P is covered with the heat insulating material H.

  The pressure gauge 16 is attached to the downstream side of the measurement heater 12 and measures the pressure of the steam flowing in the pipe P. The pressure gauge 16 may be attached to the downstream side of the measurement heater 12 as shown in FIG. 1 or may be attached to the upstream side of the preheater 11, and between the preheater 11 and the measurement heater 12 It may be attached to Further, a plurality of pressure gauges 16 may be provided. For example, the conditions are the upstream side of the preheater 11 and the downstream side of the measurement heater 12.

  The pre-heater control device 17 refers to the temperature measured by the temperature measurement unit 13 and controls the pre-heater 11 so that all the moisture of the vapor input to the inside of the pre-heater 11 evaporates. For example, the preheater control device 17 performs feedback control of the preheater 11 by performing PID (proportional integral derivative) control so that the measurement result of the temperature measurement unit 13 becomes constant. Here, the preheater control device 17 determines that the temperature measured by the temperature measurement unit 13 is a temperature (for example, a temperature higher by several to dozens of degrees C.) higher by a predetermined temperature than the saturated vapor temperature in the pipe P. The preheater 11 is controlled to be as follows. This temperature is set so that all the moisture of the steam input into the inside of the preheater 11 can be evaporated.

  Note that by setting the control target temperature to a temperature that is several to dozens of degrees higher than the saturated steam temperature, as described later, even if the steam with a high degree of humidity is input and the temperature drops, the saturated steam temperature or more is secured Because it can be done, temperature control is easy. On the other hand, if the control target temperature is the saturated steam temperature (or a temperature slightly higher than the saturated steam temperature), the steam with a high degree of humidity is input and the temperature drops immediately after the temperature drops. It will be difficult.

  The heater power supply 18 supplies power for heating the measurement heater 12 to the measurement heater 12. The heater power supply 18 controls the power supplied to the measuring heater 12 based on temperature changes at one or more points in the direction of the pipe axis of the pipe P caused by the heating of the measuring heater 12. Such control is performed to accurately measure the flow velocity of the steam flowing in the pipe P.

  In the present embodiment, in order to simplify the description, the case where the heater power supply 18 controls the power based on the temperature change at one point in the tube axis direction will be described as an example. Specifically, based on the measurement result (average value) of the temperature sensor (temperature sensor SN in FIG. 2) provided at the portion where the measurement heater 12 is attached, the power supplied to the measurement heater 12 is Control feedback. Thus, the reason why the power supplied to the measurement heater 12 is controlled based on the measurement result of the temperature sensor SN is to prevent the temperature of the pipe P from becoming equal to or higher than the heat resistant temperature. Incidentally, instead of the measurement result of the temperature sensor SN, the power supplied to the measurement heater 12 is controlled based on the measurement result of the sensor group arranged at a distance of 0 mm from the end of the measurement heater 12 You may Hereinafter, the measurement result of the temperature input to the heater power supply 18 is referred to as “one-point measurement result”.

  When the temperature change at one point in the pipe axis direction of the pipe P (change in one point measurement result) caused by the heating of the measurement heater 12 is equal to or less than a preset threshold value, the heater power supply 18 Control to gradually increase the supplied power is performed. For example, assuming that the one-point measured temperature obtained when heating of the measurement heater 12 is not performed is 175 ° C. (the temperature of steam), the one-point measured temperature obtained by the heating of the measurement heater 12 does not reach 180 ° C. (When the change in one-point measurement result is 5 ° C. or less), the heater power supply 18 performs control to gradually increase the power supplied to the measurement heater 12 (for example, by 1 [W] each). Such control is performed in order to supply appropriate power to the measurement heater 12 in order to accurately measure the flow velocity of the steam flowing in the pipe P.

  The data collection device 19 is a device that collects various data used in the measurement system 1. Specifically, the data acquisition device 19 indicates data indicating the measurement results of the temperature measuring units 13 to 15 and the pressure gauge 16, data relating to control of the preheater 11 (a voltage applied to the preheater 11 and a current flowing to the preheater 11). Data) and data of the heater power supply 18 (data indicating the voltage applied to the measurement heater 12 and the current flowing to the measurement heater 12) are collected. As the data collection device 19, a device called a so-called data logger can be used.

  The data processing device 20 uses the data collected by the data collection device 19 to determine the flow velocity of the steam flowing in the pipe P. Specifically, the data processing device 20 obtains the flow velocity based on the data indicating the measurement results of the temperature measurement units 14 and 15. Here, the temperature distribution (temperature distribution on the surface of the pipe P in the direction of the pipe axis of the pipe P) caused by the pipe P being heated by the measurement heater 12 decreases as the flow rate increases, and conversely, the flow rate decreases. growing. Since the measurement result of the temperature measurement unit 15 changes in conjunction with the change of the temperature distribution, the flow velocity of the steam flowing in the pipe P can be obtained from the data indicating the measurement result of the temperature measurement unit 15.

  FIG. 3 is a block diagram showing the main configuration of a data processing apparatus provided in the measurement system according to the first embodiment of the present invention. As shown in FIG. 3, the data processing apparatus 20 includes an input unit 21, a data acquisition unit 22, a data processing unit 23, a memory 24, and a display unit 25. The data processing device 20 can be realized by, for example, a computer such as a personal computer.

  The input unit 21 includes an input device such as a keyboard and a pointing device, and inputs various instructions from the outside. The data acquisition unit 22 acquires various data collected by the data collection device 19 under the control of the data processing unit 23 based on the instruction input from the input unit 21. The data processing unit 23 obtains the flow velocity of the steam flowing in the pipe P using the various data acquired by the data acquisition unit 22 and the various data stored in the memory 24 based on the instruction input from the input unit 21.

  The memory 24 is, for example, a volatile or non-volatile memory (semiconductor memory), and stores various data necessary to obtain the flow velocity of the steam flowing in the pipe P. For example, data in which the flow velocity of the steam flowing in the pipe P and the temperature distribution in the pipe axis direction of the outer peripheral surface of the pipe P are associated is stored. The display unit 25 includes, for example, a display device such as a liquid crystal display device, and displays the flow velocity of the vapor flowing in the pipe P obtained by the data processing unit 23.

  Next, measurement errors generated in the measurement system according to the first embodiment of the present invention will be described. Drawing 4 is a figure showing an example of temperature distribution of the surface of piping in the direction of a pipe axis of piping formed in a 1st embodiment of the present invention. In the graph shown in FIG. 4, the horizontal axis represents the position in the direction of the pipe axis of the pipe P, and the vertical axis represents the temperature. Further, it is assumed that the centers of both ends of the measurement heater 12 are disposed at the position of 0.5 [m] on the horizontal axis of the graph shown in FIG.

  In the graph shown in FIG. 4, the power supplied to the measurement heater 12 is constant (eg, 70 [W]), and the measured values of the temperature measurement units 14 and 15 when the flow velocity of the steam flowing in the pipe P is changed It is a graph which shows an analysis value. Specifically, the graph shown in FIG. 4 (a) is a graph when the flow velocity of the steam flowing in the pipe P is set to 2 [m / s], and the graph shown in FIG. 4 (b) is a pipe P It is a graph at the time of setting the flow velocity of the steam which flows inside to 4 [m / s].

  First, referring to FIG. 4B, it can be seen that although a slight deviation is observed between the measured value and the analysis value, the measured value substantially matches the analysis value. On the other hand, referring to FIG. 4A, it can be seen that the deviation of the measured value from the analysis value is large. From FIGS. 4 (a) and 4 (b), even if the power supplied to the measurement heater 12 is constant, when the flow velocity of the steam flowing in the pipe P becomes slow, the deviation of the measured value from the analysis value is large. It turns out that it becomes. This is because, when the flow velocity of the steam flowing in the pipe P is low, the heat generated from the measurement heater 12 can not be absorbed by the boundary layer and is dissipated, and the temperature in the vicinity of the pipe wall of the pipe P is It is considered to be because it is lower than the analysis value.

  FIG. 5 is a diagram showing the evaluation result of the measurement error in the first embodiment of the present invention. FIG. 5 shows the results of evaluating the degree of coincidence (see FIG. 4) of the measured values with the analysis values by changing the power supplied to the measurement heater 12 and the flow rate of steam flowing in the pipe P. . In the example shown in FIG. 5, the power supplied to the measurement heater 12 is changed to 25 [W], 45 [W], 70 [W], and 159 [W], and the flow rate of the steam flowing in the pipe P is It is changed to 2 [m / s], 4 [m / s], 8 [m / s], 10 [m / s], 20 [m / s], and 30 [m / s].

The evaluation results shown in FIG. 5 are as follows.
○: good agreement between the analysis value and the actual measurement value Δ: slight agreement between the analysis value and the actual measurement value ×: mismatch between the analysis value and the actual measurement value −: measurement not performed (measurement is difficult because the power is too small)

  Referring to FIG. 5, when relatively large power is supplied to the measurement heater 12 and the flow velocity of the steam flowing in the pipe P is relatively slow, the analysis value and the actual value do not match. I understand that. Further, referring to FIG. 5, when the flow velocity of the steam flowing in the pipe P is relatively fast under the condition where relatively small power is supplied to the measurement heater 12, it is supplied to the measurement heater 12. It can be seen that measurement is difficult because the power is too small.

  From the above, when the flow rate of the steam flowing in the pipe P is relatively fast, the power supplied to the measuring heater 12 is increased, and when the flow rate of the steam flowing in the pipe P is relatively slow, the measuring heater 12 is used. It is considered that if the supplied power is reduced, the analysis value and the measured value can be made to coincide. If such power control is performed, the actual measurement value can be made to coincide with the analysis value, and as a result, it is considered that the flow velocity of the steam flowing in the piping P can be measured with high accuracy.

  However, if the power supplied to the measurement heater 12 is made too large or too small, it may be considered that the analysis value and the actual value may be inconsistent, making measurement difficult. Therefore, in the present embodiment, as described above, the temperature change at one point (change in one-point measurement result) in the direction of the pipe axis of the pipe P caused by the heating of the measuring heater 12 by the heater power supply 18 is less than a preset threshold. In this case, control is performed to gradually increase the power supplied to the measurement heater 12.

  Next, a measurement method by the measurement system 1 in the above configuration will be described. Here, in order to simplify the description, it is assumed that the steam is generated by the steam generating device E1 and the generated steam is supplied to the load facility E2 through the pipe P. When the power supply of the measurement system 1 is turned on, the temperature measurement unit 13 measures the temperature, and the temperature measured by the temperature measurement unit 13 is referred to, and the preheater control device is such that all the moisture of the vapor evaporates. The preheater 11 is controlled by 17. For example, the temperature measured by the temperature measurement unit 13 is controlled to be constant.

  In parallel with the above operation, electric power is supplied from the heater power supply 18 to the measurement heater 12, and the pipe P is heated by the measurement heater 12 (first step). For example, electric power of 25 [W] is supplied from the heater power supply 18 to the measurement heater 12, and the pipe P is heated by the measurement heater 12. Here, since the steam from the steam generating device E1 flows in the pipe P, the heat transfer in the pipe P changes.

  Then, the temperature sensor SN shown in FIG. 2 measures the temperature at one point in the pipe axis direction of the pipe P, and the measurement result (one-point measurement result) is input to the heater power supply 18. Then, the heater power supply 18 determines whether the input one-point measurement result exceeds a preset threshold (for example, 5 ° C.). If it is determined that the one-point measurement result does not exceed the threshold, the heater power supply 18 performs control to gradually increase the power supplied to the measurement heater 12 (second step).

  On the other hand, if it is determined that the one-point measurement result exceeds the threshold (or if it is determined that the one-point measurement result exceeds the threshold), the temperature on the upstream side of the measurement heater 12 is the temperature measurement unit While being measured at 14, the temperature on the downstream side of the measurement heater 12 is measured by the temperature measurement unit 15 (third step). Data indicating the measurement results of the temperature measurement units 14 and 15 is acquired by the data acquisition unit 22 of the data processing device 20 after being collected by the data acquisition device 19.

  Then, in the data processing unit 23, processing for obtaining the flow velocity of the steam flowing in the pipe P using the data acquired by the data acquisition unit 22 is performed (fourth step). The flow velocity of the steam flowing in the pipe P is, for example, the data acquired by the data acquiring unit 22 and the data stored in the memory 24 (flow velocity of the steam flowing in the pipe P and the axial direction of the outer peripheral surface of the pipe P It is determined by comparing with the temperature distribution and the associated data). When the above processing is completed, information indicating the flow velocity of steam is output to the display unit 25 and displayed.

  As described above, according to the present embodiment, the predetermined portion of the surface of the pipe P is heated by the measuring heater 12 and the heating of the measuring heater 12 causes the temperature change at one point in the pipe axis direction of the pipe P for measurement The electric power supplied to the heater 12 is controlled, the temperature distribution on the surface of the pipe P in the direction of the pipe axis is measured by the temperature measuring units 14 and 15, and the flow velocity of steam is calculated based on the measurement results of the temperature measuring units 14 and 15. I am trying to do it. Thereby, the flow velocity of the steam which flows in the inside of piping P from the exterior of piping P can be measured with sufficient accuracy.

Second Embodiment
Next, a measurement system according to a second embodiment of the present invention will be described. The measurement system of the present embodiment has substantially the same configuration as the measurement system 1 of the first embodiment shown in FIG. 1, but differs in that a heater power supply 18 that performs control different from that of the first embodiment is provided. Specifically, the heater power supply 18 in the above-described first embodiment performs control to gradually increase the power supplied to the measurement heater 12 when the change in the single-point measurement result is equal to or less than a preset threshold. Met. On the other hand, the heater power supply 18 in this embodiment controls the power supplied to the measurement heater 12 according to the one-point measurement result, using the table TB (correspondence information) shown in FIG.

  FIG. 6 is a view showing a table used in the measurement system according to the second embodiment of the present invention. As shown in FIG. 6, the table TB used by the heater power supply 18 in the present embodiment is a table in which a change in temperature (change in one-point measurement result) is associated with the power to be supplied to the measurement heater 12. This table TB is prepared for each temperature and pressure of steam. The table TB illustrated in FIG. 6 is in units of 5 [° C.], but the unit of temperature is arbitrary. Note that, instead of the table shown in FIG. 6, a function may be used in which a change in temperature (change in one-point measurement result) and the power to be supplied to the measurement heater 12 are associated.

  When the power supply of the measurement system of this embodiment is turned on, the temperature measurement unit 13 measures the temperature as in the measurement system 1 of the first embodiment, and the temperature measured by the temperature measurement unit 13 is referred to The preheater control device 17 controls the preheater 11 so that all the moisture of the vapor evaporates. For example, the temperature measured by the temperature measurement unit 13 is controlled to be constant.

  In parallel with the above operation, electric power is supplied from the heater power supply 18 to the measurement heater 12, and the pipe P is heated by the measurement heater 12 (first step). For example, electric power of 25 [W] is supplied from the heater power supply 18 to the measurement heater 12, and the pipe P is heated by the measurement heater 12.

  Then, the temperature sensor SN shown in FIG. 2 measures the temperature at one point in the pipe axis direction of the pipe P, and the measurement result (one-point measurement result) is input to the heater power supply 18. Then, the control corresponding to the input one-point measurement result (or the power corresponding to the temperature closest to the input one-point measurement result) is acquired from the table TB, and the control to supply the acquired electric power to the measurement heater 12 is It is performed by the heater power supply 18 (second step). At this time, the measurement result of the pressure gauge 16 and the temperature sensor (not shown) (a temperature provided between the preheater 11 and the measurement heater 12 and not affected by the heat generated from the preheater 11) A table TB corresponding to the measurement result of the sensor) is used.

  Next, the temperature measurement unit 14 measures the temperature on the upstream side of the measurement heater 12, and the temperature measurement unit 15 measures the temperature on the downstream side of the measurement heater 12 (third step). Data indicating the measurement results of the temperature measurement units 14 and 15 is acquired by the data acquisition unit 22 of the data processing device 20 after being collected by the data acquisition device 19. Then, in the data processing unit 23, processing for obtaining the flow velocity of the steam flowing in the pipe P using the data acquired by the data acquisition unit 22 is performed (fourth step). In addition, the flow velocity of the steam which flows through the inside of piping P is calculated | required by the method similar to 1st Embodiment. When the above processing is completed, information indicating the flow velocity of steam is output to the display unit 25 and displayed.

  As described above, according to the present embodiment, as in the first embodiment, a predetermined portion of the surface of the pipe P is heated by the measurement heater 12, and heating of the measurement heater 12 causes one point in the pipe axis direction of the pipe P The power supplied to the measurement heater 12 is controlled based on the change in temperature, the temperature distribution on the surface of the pipe P in the direction of the pipe axis is measured by the temperature measurement units 14 and 15, and the measurement results of the temperature measurement units 14 and 15 Based on the above, the flow velocity of steam is calculated. Thereby, the flow velocity of the steam which flows in the inside of piping P from the exterior of piping P can be measured with sufficient accuracy.

  Further, in the present embodiment, the temperature control is performed using the table TB in which the change in the one-point measurement result is associated with the power to be supplied to the measurement heater 12. For this reason, compared with the first embodiment in which the power supplied to the measurement heater 12 is controlled to be gradually increased, the flow velocity of the steam flowing in the pipe P can be accurately measured in a short time with high accuracy.

  Although the measurement system and method according to the embodiment of the present invention have been described above, the present invention is not limited to the above embodiment and can be freely changed within the scope of the present invention. For example, in the embodiment described above, an example of measuring the flow velocity of water vapor generated by the vapor generation device E1 has been described, but the present invention can also be applied to, for example, measurement of LNG (liquefied natural gas) vapor . Not only the flow rate of steam but also the flow rate of steam can be measured, or both the flow rate and flow rate of steam can be measured.

  Moreover, in the said embodiment, the example which measures the flow velocity based on the temperature distribution of the surface in the pipe-axis direction of the piping P measured by the temperature measurement parts 14 and 15 was demonstrated. However, the flow velocity may be measured based on the temperature of one point inside or near the measurement heater 12 in the pipe axis direction of the pipe P. For example, the flow velocity may be measured based on the measurement result (average value) of any one of the sensor groups provided in the temperature measurement units 14 and 15, or the temperature sensor SN shown in FIG. The flow velocity may be measured based on the measurement result (average value) of

  Moreover, in embodiment mentioned above, although the preheater 11 and the heater 12 for measurement which were provided in the piping P mentioned as the example the structure covered with the heat retention material H, it is not limited to this. For example, when the data processing apparatus 20 performs processing to correct data indicating the measurement results of the temperature measurement units 14 and 15 in consideration of heat radiation from the surface of the pipe P, the surface of the pipe P is kept warm. It may not be coated with the material H. Alternatively, only a part of the surface of the pipe P (the installation part of the temperature measurement units 13 to 15) may be covered with the heat insulating material H.

  In the embodiment described above, the pre-heater control device 17, the heater power supply 18, the data acquisition device 19, and the data processing device 20 are separately provided, but they are integrally provided. Also good. The preheater 11, the temperature measurement unit 13, and the preheater control device 17 can be omitted.

DESCRIPTION OF SYMBOLS 1 measurement system 11 preheater 12 heater for measurement 13 temperature measurement unit 14 temperature measurement unit 15 temperature measurement unit 17 preheater control device 18 heater power supply 20 data processing device P piping TB table

Claims (10)

In a measurement system that measures the flow velocity of steam flowing in piping,
A heat exchanger that exchanges heat with a predetermined portion of the surface of the pipe;
A first control unit that controls a heat exchange amount of the heat exchanger on the basis of a temperature change at one point or a plurality of points in a pipe axial direction of the pipe caused by heat exchange of the heat exchanger;
A first temperature measurement unit that measures the temperature of one or more points of the surface in the direction of the pipe axis of the pipe;
A calculation unit that calculates the flow velocity of the steam based on the measurement result of the first temperature measurement unit. The heat exchanger is a heating device,
The measurement system according to claim 1, wherein the first control unit controls power supplied to the heating device.   The measurement system according to claim 2, wherein the heating device is a ring-shaped heater.   4. The control method according to claim 2, wherein the first control unit performs control to gradually increase the power supplied to the heating device when the temperature change is equal to or less than a preset threshold. Measurement system described.   The first control unit associates the temperature change with the power to be supplied to the heating device, and includes correspondence information prepared for each of the temperature and pressure of the steam, and refers to the correspondence information. The measurement system according to claim 2 or 3, further comprising controlling power supplied to the heating device. A preheating unit attached to an outer peripheral surface of the pipe upstream of the predetermined portion;
A second temperature measurement unit attached to an outer peripheral surface of the pipe between the preheating unit and the predetermined portion;
A second control unit for controlling the preheating unit such that all moisture of the vapor evaporates by referring to the temperature measured by the second temperature measurement unit. Item 5. The measurement system according to any one of Items 5.   The measurement system according to claim 6, wherein the second temperature measurement unit is attached downstream of the preheating unit and in the vicinity of the preheating unit.   The measurement system according to claim 6 or 7, wherein the second temperature measurement unit is attached to a bottom portion of an outer peripheral surface of the pipe.   The second control unit controls the preheating unit such that the temperature measured by the second temperature measurement unit is constant. Measurement system. A measuring method for measuring the flow velocity of steam flowing in a pipe,
A first step of heat exchange with a predetermined portion of the surface of the pipe;
A second step of controlling a heat exchange amount of the heat exchange based on a temperature change at one point or a plurality of points in an axial direction of the pipe caused by the heat exchange performed in the first step;
A third step of measuring the temperature of one or more points of the surface in the axial direction of the pipe;
And a fourth step of calculating the flow velocity of the steam based on the measurement result of the third step.

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