KR100536211B1 - Electric Conductivity-Type Fouling Monitoring System and Method thereof - Google Patents

Abstract

The present invention relates to a capstone measuring device for measuring capstone adsorbed on a pipe of a heat exchanger used in a power plant, an industrial boiler, a cooling system, and a capstone measuring method using the device. It is convenient to use in the field, and it is convenient to maintain the device such as the exchange of sensor in case of sensor failure, and it is not sensitive to flow fluctuation or temperature change of circulating fluid because it measures the capstone using electric conductivity. In addition to the room, you can check the degree of adsorption of the capstone in real time through the touch screen, and it is easy to collect capstone attached to the heating electrode of the measuring sensor without disassembling the device. Can be displayed on the touch screen and an external monitor. It will use the touch screen on the electrical conductivity capable of changing the default value setting method Capstone measuring apparatus and method without.

 The capstone measuring device of the present invention is connected to the inlet end and the flow rate control valve for adjusting the flow rate of the introduced fluid; A reference sensor without a heating wire that measures the electrical conductivity when the capstone is not adsorbed, a measuring sensor with a heating wire that measures the electrical conductivity when the capstone is adsorbed, and a flow measuring sensor that measures the flow rate of the fluid A sensor unit configured to include; A circuit unit for receiving and processing various sensor signals of the sensor unit; It is characterized in that it comprises a touch screen for receiving a variety of data calculated by the circuit unit and displays it on the screen and changes the default setting value according to the user's request.

Description

Electrical conductivity type capstone measuring device and method for measuring capstone using the device {Electric Conductivity-Type Fouling Monitoring System and Method

The present invention relates to a capstone measuring device for measuring capstone adsorbed on a pipe of a heat exchanger used in a power plant, an industrial boiler, a cooling system, and a capstone measuring method using the device. It is convenient to use, and it is convenient to maintain the device such as the exchange of sensor in the event of sensor failure, and because it measures the capstone using electric conductivity, it is not sensitive to flow fluctuation or temperature change of circulating fluid. In addition, it is possible to check the adsorption degree of capstone in real time through the touch screen in the field, and it is easy to collect capstone attached to the heating electrode of the measuring sensor without disassembling the device. Display on the monitor and on an external monitor, and without the need to disassemble and Using a lean relates to electrical conductivity capable of changing the default value setting method Capstone measuring apparatus and method.

Many heat exchangers are used in various industrial fields such as power plants, industrial boilers, cooling systems, and the like, and various fluids flow in these heat exchangers. These fluids contain various substances such as silica, calcium carbonate, microorganisms, carbon, and the like, and these various substances react with other components or decrease in solubility as the temperature decreases during heat exchange, so they are deposited on the surface of the heat exchanger to form capstone. do. These capstones lower the heat transfer efficiency of the heat exchanger, thereby lowering the energy efficiency and causing the pressure loss of the fluid to shorten the life of various devices.

Therefore, the problem of grasping the adsorption degree of the capstone, collecting the capstone to analyze the components, and selecting the cleaning cycle has a direct influence on the heat efficiency and life of the heat exchanger.

Conventionally, in order to measure the capstone and to set the cleaning cycle, a primitive method of visually determining the degree of adsorption of capstone by cutting the pipe from the heat exchanger was used. However, such a method is not only accurate data calculation, but also has a problem that there is no reliability in selecting the cleaning cycle. In addition, although not shown, a tube inlet / outlet water temperature sensor and a precision flow rate measuring sensor are installed in one heat exchanger tube, and one tube is blocked. The method of measuring the cleanliness of the tube by calculating the heat transfer coefficient based on the inlet temperature and the condensate temperature is used. This method requires expensive heat exchanger modifications and requires a change in the structure of the field equipment. It has been pointed out that maintenance is difficult and the measured values obtained are not accurate. Also, As confirmed by the heat transfer coefficient equation, since the heat transfer coefficient uses the temperature change, the cleanliness measured according to the flow fluctuation is different. For reference, the heat transfer between the fluid and the pipe in the pipe is caused by the heat transfer form of radiation and convection, where the convective heat transfer coefficient is proportional to the speed of the fluid. The smaller value of the heat transfer coefficient has been shown by heat transfer theory.

The present invention has been made to solve the problems of the prior art described above, the object of the present invention is to be easily removable in any part of the pipe is easy to use and maintenance of the device, such as replacement of the sensor in the event of sensor failure It is convenient to use and the electric conductivity is used to measure the capstone, so it is not affected by the fluctuation of the flow rate or the temperature of the circulating fluid, and you can check the degree of adsorption of the capstone in real time through the touch screen not only in the control room but also in the field. The present invention provides an electroconductive capstone measuring apparatus and capstone measuring method using the apparatus, which can collect capstones attached to the heating electrode of the measuring sensor without disassembling the apparatus.

Another object of the present invention, in addition to the above object, can display various measured or calculated data on the touch screen and the external monitor, the electrical conductivity method that can change the default settings using the touch screen without disassembling the device The present invention provides a capstone measuring apparatus and a capstone measuring method using the apparatus.

The present invention has the following configuration to achieve the above object.

According to a first embodiment of the present invention, the capstone measuring apparatus of the present invention includes: a flow rate control valve connected to an inlet end and controlling a flow rate of an introduced fluid; A reference sensor without a heating wire that measures the electrical conductivity when the capstone is not adsorbed, a measuring sensor with a heating wire that measures the electrical conductivity when the capstone is adsorbed, and a flow measuring sensor that measures the flow rate of the fluid A sensor unit configured to include; A circuit unit for receiving and processing various sensor signals of the sensor unit; It is characterized in that it comprises a touch screen for receiving a variety of data calculated by the circuit unit and displays it on the screen and changes the default setting value according to the user's request.

According to the second embodiment of the present invention, the capstone measuring device of the present invention, in the first embodiment, the reference sensor, at least one reference formed at a predetermined interval along the circumference and the reference cavity with its front end opened A reference external electrode having a through hole, a reference body having a reference center hole for fixing the reference outer electrode and communicating with the reference cavity, and a reference inserted into the cavity of the reference external electrode through the reference center hole of the reference body An internal electrode; The measuring sensor includes a measuring outer electrode having a measuring cavity having an open front end and at least one measuring through-hole formed at predetermined intervals along a circumference thereof, and a measuring center for fixing the measuring outer electrode and communicating with the measuring cavity. A measuring body having a ball and a measuring inner electrode inserted into the cavity of the measuring outer electrode through the measuring center hole of the measuring body, wherein the measuring inner electrode has a heating wire spirally wound therein; The reference sensor and the measurement sensor is provided with a screw thread on the outer peripheral surface of the main body is characterized in that it can be freely attached to the pipe.

According to the third embodiment of the present invention, in the capstone measuring apparatus of the present invention, in the second embodiment, a temperature measuring element is integrally formed on the reference internal electrode and the measurement internal electrode, and the reference sensor and the measurement sensor The inner electrode, the outer electrode and the main body is characterized in that can be attached to each other.

According to the fourth embodiment of the present invention, the capstone measuring apparatus of the present invention, in the first embodiment, the circuit portion, an AC power supply unit connected in series to the measurement sensor and the reference sensor to apply an AC power source, A conversion amplifier for receiving and converting a flow signal, a measurement conductivity signal, and a reference conductivity signal from the sensor unit, an analog switch for channel-selecting and transmitting the amplified signals, and an AD converter for AD conversion of the sensor signals; And a central processor configured to calculate the flow rate, the electrical conductivity of the reference sensor, the electrical conductivity of the measurement sensor, and the cleanliness index based on a predetermined equation, and transmit the digital signals to the touch screen through a touch screen communication unit for display. It characterized in that it comprises a storage unit for storing data.

According to the fifth embodiment of the present invention, the capstone measuring device of the present invention, in the fourth embodiment, wherein the circuit portion further includes an external monitor communication portion to communicate the cleanliness index calculated with the various data. It can be transmitted to the external monitor of the control room.

According to the sixth embodiment of the present invention, the capstone measuring method of the present invention comprises the step of applying an AC power to the reference sensor and the measurement sensor, the reference conductivity signal from the reference sensor, the measurement conductivity signal from the measurement sensor A measurement step of measuring a flow signal from the flow sensor and measuring voltage and current applied to the measurement sensor, an AD conversion step of converting the various signals to an AD converter, and a central processing unit to the converted digital signal; A calculation step for calculating the flow rate, the electrical conductivity of the reference sensor, the electrical conductivity of the measuring sensor and the cleanliness index according to a predetermined formula, and transmits and displays the calculated data on the touch screen in real time, and stores these data in real time It characterized in that it comprises a display and storing step to store in the wealth.

According to the seventh embodiment of the present invention, the capstone measuring method of the present invention, in the sixth embodiment, the alarm judgment step of determining whether the calculated flow rate exceeds the reference value, and the alarm determination step result reference value is exceeded And further comprising an alarm performing step of performing an alarm visually or visually.

According to an eighth embodiment of the present invention, in the capstone measuring method of the present invention, in the sixth embodiment, the measuring step further comprises: measuring a reference temperature signal from a reference sensor and a measurement temperature signal from a measurement sensor; The calculation step includes a step of calculating a cleanliness coefficient with a heat transfer coefficient, and the displaying and storing step is to display and store the cleanliness coefficient calculated with the electrical conductivity and the cleanliness coefficient calculated with the heat transfer coefficient together. It is characterized by including.

Applicants will now be described in detail embodiments of the present invention with reference to the accompanying drawings.

The capstone measuring device 100 includes a flow control valve 160, a sensor unit 10, a circuit unit 20, a touch screen 400, and a DC power supply unit 5.

As shown in FIG. 1, the flow regulating valve 160 is not shown in detail, but is connected to the inlet end and controls a flow rate of the fluid flowing from the heat exchanger. It includes all electric valves that are controlled as electrical signals. The reason for adjusting the flow rate of the fluid is that the adsorption degree of the capstone attached to the heating surface of the heater sensor differs according to the flow rate, so the capstone according to the flow rate is controlled by adjusting the flow rates. This is to observe the degree of adsorption of. It has been found through experiments that the adsorption of capstone is low at high flow rates and that of capstone is high at low flow rates.

As shown in FIG. 6, the sensor unit 120 includes a reference sensor 125, a measurement sensor 120, and a flow sensor 170.

The reference sensor 125 and the measurement sensor 120 basically include a main body 1251 and 1201, external electrode bars 1252 and 1202, internal electrode bars 1253 and 1203, and a connection member 1204. The fluid flowing inside the heat exchanger contains various impurities in the water, and these impurities have an electrical polarity. Here, the internal electrode and the external electrode are provided in the reference sensor or the measurement sensor to allow the capstone to be adsorbed on the inner electrode using the characteristics of such impurities and to determine the degree of adsorption of the capstone using the change in electrical conductivity.

Hereinafter, the common points of the reference sensor or the measurement sensor will be described first, and the characteristics of each sensor will be described next. In addition, in the present application, in order to distinguish common parts between the reference sensor and the measurement sensor, the term 'reference' is attached to the components of the reference sensor and the term 'measurement' is attached to the components of the measurement sensor.

Both the reference sensor and the measuring sensor have a main body, an external electrode, an internal electrode, and a connecting member.

The main bodies 1251 and 1201 may be made of an insulating material such as Teflon, and may include insertion holes 1251b and 1201b and bolts for accommodating the center holes 1251a and 1201a and the connecting members 1254 and 1204 formed along the center line thereof. Bolt holes 1251c and 1201c for accommodating 1255 and 1205 are provided, and on the outer circumferential surface there are several stepped portions formed with screw portions 1251d, 1201d, 1251e, and 1201e. here,

The external electrode rods 1252 and 1202 may include the cavity portions 1252a and 1202a having their front ends opened, a plurality of through holes 1252b and 1202b formed along the circumference thereof, and the thread portions 1252c and 1202c formed on the inner circumferential surface of the end of the cavity portion. It is suitable to be made of a material having corrosion resistance and electrical conductivity, and preferably made of titanium. The cavity and the through hole serve as a flow path through which fluid in the pipe can flow. That is, the fluid flowing into the cavity flows out through the through hole.

The connecting members 1254 and 1204 are used to connect the AC power line A to the external electrode, and are composed of connecting pieces 1254c and 1204c having connecting rods 1254a and 1204a and bolt holes 1254b and 1204b. Made of a conductive material. Here, the bolt member is provided in the connecting member to improve the battery coupling between the connecting piece and the external electrode rod with the bolt.

The inner electrode rods 1253 and 1203 are inserted into the cavity of the outer electrode rod and have electrode threads 1253a and 1203a at their ends, and are made of a material having corrosion resistance and electrical conductivity. In order to simulate the same pipe, the same material as the pipe is suitable.

2B, 3A and 4A, these coupling relations are shown. The external electrodes are coupled to the main body by screwing the threaded portions 1252c and 1202c at the end of the cavity of the external electrode to the threads 1251d and 1201d at the outer peripheral surface of the end of the main body. Then, after inserting the inner electrode into the center hole of the main body, the screw parts 1253a and 1203a of the outer peripheral surface of the end of the inner electrode are screwed into the screw parts 1251a and 1201a of the inner circumferential surface of the center hole of the main body to fasten the inner electrode to the main body Insert the connecting rods 1254f and 1204f of the connecting members 1254 and 1204 into the insertion holes 1251b and 1201b of the main body, and then fix them with bolts 1255 and 1205 and fix the bolts to the bolt holes 1254b and 1204b of the connecting piece. (Not shown) to attach the connecting pieces 1254c and 1204c to the external electrode to closely attach the connecting member to the main body, thereby completing the assembly of the sensor.

Meanwhile, unlike the reference sensor, the measurement sensor 120 further includes a heating wire 1203a wound in a spiral shape to make the heat load of the heat exchanger and the heat load of the measurement sensor the same, and a DC power is applied to the heating wire. (See Figure 6). Since the degree of adsorption of the impurities in the fluid varies depending on the temperature conditions, in order to accurately measure the capstone adsorbed on the heat exchanger, the heat load of the heat exchanger and the heat load of the measuring sensor must be equalized.

Reference sensor 125 'and measurement sensor 120' according to another embodiment of the present invention are shown in Figures 3b and 4b. Reference numerals appended to these sensors refer to the reference numerals of the reference sensor and the measurement sensor described above, and the temperature measuring elements 1253b 'and 1253b' built in the internal electrodes 1253 'and 1203'. Except for the configuration other than the same as the sensor seen earlier. The temperature measuring device is a device for measuring the temperature of the fluid, PT100Ω sensor can be used, the temperature in the reference sensor in the state that the capstone is not adsorbed (hereinafter referred to as 'reference temperature', T1), the capstone is adsorbed It can be installed when calculating the heat transfer coefficient by measuring the temperature (hereinafter referred to as 'measurement temperature', T2) in the measuring sensor of and using this to calculate the cleanliness coefficient, which will be described below.

5 is a view illustrating a process of attaching and detaching a reference sensor and a measuring sensor of the present invention. Referring to FIG. 5, the reference sensor and the measurement sensor can be easily attached to the pipe by screwing the screw parts 1251e and 1250e formed on the outer circumferential surface of the main body to the pipe part of the pipe. Not only can the sensor be removed from the pipe, but the sensor can be installed and removed from any part of the pipe.

The flow sensor 170 is used to measure the flow rate of the fluid flowing through the flow path, SEBA CYCLONE TUBBINE FLOWMETER series sold by Seva Corporation may be used. The reason for measuring the flow rate is as described above.

6 is a block diagram of a capstone measuring apparatus including a DC power supply unit 5, a sensor unit 10, a circuit unit 20, and a touch screen 400.

The DC power supply unit 5 applies a DC voltage to the measurement sensor to make the heat load of the heat exchanger and the heat load of the measurement sensor the same, and a 1000 W class high capacity power supply is used.

The circuit unit 20 measures the reference conductivity signal, the measurement conductivity signal, the voltage (V), the current (A), and the flow rate (FL) of the sensor unit 10 and uses these data to measure electrical conductivity and The cleanliness index is calculated and transmitted to the touch screen 400 and the external monitor 420 for display or to cause the alarm unit 430 to perform an alarm. Specifically, the circuit unit 20 may include an AC power supply unit 270, conversion amplifiers 210, 212, 214, and 216, an analog switch 220, an AD converter 222, a central processor 224, a storage unit 250, The touch screen communication unit 242, an external monitor communication unit 240, and DA converters 226, 260, and 265 are included.

The AC power supply unit 270 supplies AC power to the reference sensor 125 and the measurement sensor 120 to measure the electrical conductivity. When AC power is applied to the reference sensor and the measurement sensor, the signal output from the sensor varies according to the degree of adsorption of the capstone of the internal electrode. Since the capstone is not adsorbed on the reference sensor with no internal heating wire, the resistance due to the adsorbed capstone is minimized, while the capstone is adsorbed on the measuring sensor with the heating wire that takes the same heat load as the heat load of the heat exchanger. Will increase. Therefore, the electrical conductivity of the measuring sensor is lower than the electrical conductivity of the reference sensor, and the adsorption degree of the capstone is determined using the same principle. Electrical conductivity (C) and cleanliness index (FI) are calculated by the following arithmetic formula.

Where V _IN is the AC voltage input to the sensor, V _OUT is the AC voltage output from the sensor (reference conductivity signal, measurement conductivity signal), R _S is the resistance of the reference sensor or measurement sensor, C is the electrical conductivity of the sensor, C _M is the conductivity of the measuring sensor and C _S is the conductivity of the reference sensor. The unit of V is mV, the unit of R is Ω, and the unit of C is μS / cm.

In addition, conventionally, a water quality analysis method using electrical conductivity has been used. However, since the 400mV / 5kHz voltage used in this method caused the polarization of internal electrodes to separate the adsorbed capstone, the change in electrical conductivity was measured through the change in resistance due to adsorption of the capstone. It is not suitable for the present invention. Thus, Applicant uses an AC voltage of 10 mV / 1 kHz to minimize polarization. The application of the AC voltage is to prevent polarization of the electrode generated when the DC voltage is applied. When a direct current voltage is applied, due to the polarization phenomenon, the sensor component is eluted into the fluid to promote corrosion of the electrode, and the ion layer generated by the polarization phenomenon prevents adsorption of the capstone to the electrode. Here, the AC voltage means a voltage enough to prevent the polarization phenomenon, and is not limited to only 10mV.

The conversion amplifiers 210, 212, 214, and 216 amplify the reference conductivity signal and / or the reference temperature signal, the measurement conductivity signal, and / or the measurement temperature signal, voltage, current, and flow signal received from the sensor unit. In general, analog amplification circuits are used. In addition, conversion means converting the measurement values from the flow sensor 170, the measurement sensor 120, and the reference sensor 125 into a signal that can be processed on a circuit. For example, the change in the current in the flow sensor 170 is converted into a voltage signal. To convert. At this time, a known conversion circuit is used.

Referring to FIG. 7A, the conversion amplifiers 212 and 214 transforming and amplifying the measurement conductivity signal of the measurement sensor and the reference conductivity signal of the reference sensor are converted into the measurement sensor 120 and the reference sensor 125. A small voltage is applied to the AC power supply unit 270, and voltage signals are measured by the voltmeters 212b and 214b at both ends of the resistors 212a and 214a connected in series with the sensor electrode and the AC power supply unit. Amplified by 212c, 214c, and transmitted to the AD converter 222 via the analog switch 220.

In addition, as described above, the reference sensor and the measurement sensor may be equipped with a temperature measuring element on the internal electrode, in this case, the reference sensor is a reference temperature signal for the reference temperature (T1), the measurement sensor is a measurement temperature Further send the measured temperature signal for (T2). Referring to FIG. 7B, which shows a circuit diagram of a PT100Ω sensor configured as a three-wire bridge circuit, two PT100Ω sensors 1253b 'and 1203b' are connected at one end and one wire at the other end to remove the influence of the lead resistance. It is in a form that allows it. PT100Ω sensor is 100Ω at 0 ℃, so the output voltage at the output terminal is 0V, but as the temperature rises, the resistance of PT100Ω sensor rises, a voltage difference occurs at the output terminal and amplifies this voltage difference to calculate the temperature. As such, the reference temperature and the measurement temperature are used to calculate the cleanliness coefficient using the heat transfer coefficient method.

The analog switch 220, multi-channel to sequentially transmit the reference conductivity signal and / or reference temperature signal, the measurement conductivity signal and / or measurement temperature signal, voltage, current, flow rate signal amplified by the conversion amplifier unit It means a multiplexer.

The AD converter 222 converts the signal transmitted through the analog switch 220 into a digital signal, and uses a known AD converter circuit.

The central processing unit 224 is a microprocessor that calculates electrical conductivity and cleanliness index based on the flow rate, current, voltage, and the above-described equation using the converted digital signal. In addition, the central processing unit 224 determines whether or not the calculated flow rate is less than the reference value and if less than the alarm through the alarm unit 430, such as a buzzer (Buzzer) or an alarm lamp (Alarm Ramp) through the relay 228 You can also As described above, when the measurement sensor or the reference sensor is provided with a temperature measuring element and a reference temperature signal or a measurement temperature signal is sent, the reference temperature T1 and the measurement temperature T2 according to the following predetermined equations. , Voltage (V), current (A), flow rate (F / M), heat transfer coefficient (U), and cleanliness coefficient (FF) may be calculated.

 The DA converters 226, 260, and 265 convert various digital signals received from the central processor into analog signals, and known DA converters are used to generate 0-5V or 4-20mA analog signals. Using the analog signal generated through the DA conversion unit 226 to operate the analog output unit 440, such as an analog indicator, and to control the electrical flow control valve 160 using the analog signal passed through the DA conversion unit 260 In addition, the voltage applied to the heater sensor may be adjusted by controlling the DC power supply unit by using the analog signal passed through the DA converter 265 to adjust the BTU value.

The storage unit 240 stores the aforementioned various data periodically at predetermined time intervals, so that the history of the data can be grasped at any time. Various memory devices such as EEPROM and EPROM may be used as the storage unit.

The touch screen 400 is connected to the touch screen communication unit 242 of the circuit unit receives various data from the central processing unit 224 and displays it on the screen. Applicant is equipped with a touch screen in the present invention, the conventional technology that can change the default setting only when disassembling the device in the case of changing the basic setting due to the change of state of the heat exchanger and could not grasp the degree of adsorption of capstone in the field Unlike the touch screen, which is a display device that allows the user to communicate with the data processing system, the user can directly change the default setting in the field without disassembling the device and grasp the degree of adsorption of the capstone with the naked eye in the field. . As the touch screen used in the present invention, various kinds of things, such as a transparent electrode method or an infrared method, may be used. The operation principle of the touch screen is a well-known technique, and thus a detailed description thereof will be omitted.

In addition, according to another embodiment of the present invention, the capstone measuring apparatus of the present invention may further include an external monitor 420 connected to the external monitor communication unit 240 of the circuit unit. The external monitor 420 is connected to the external monitor communication unit 240, RS-232, balanced and unbalanced communication, wired and wireless modem communication, power line communication, Bluetooth communication, wired and wireless LAN communication method By remote communication with each other by the communication method, the central processing unit 224, the reference temperature (T1), measurement temperature (T2), voltage (V), current (A), flow rate (FL), cleanliness index (FI), cleanliness coefficient Various data such as (FF) and contamination coefficient (RF) are received and displayed on the screen as shown in FIG. 10A. According to another exemplary embodiment, the external monitor may receive and display an analog signal that has passed through the DA converter 226.

Referring to Figures 8 to 10b will be described in the capstone measuring method of another embodiment of the present invention.

The capstone measuring method of the present invention largely includes an AC power supply step, a measurement step, an amplification step, an AD conversion step, an operation step, a display and a storage step.

Referring to Figure 5 showing the capstone measuring method according to another embodiment of the present invention, the AC power supply step (S2, S2 ') is a small AC voltage of approximately 10mV / 1kHz suitable for preventing polarization phenomenon for electrical conductivity measurement It refers to the step of applying the to the reference sensor and the measurement sensor, the measurement step (S3, S3 ', S4') is a variety of sensors of the sensor unit 10 flow signal, reference conductivity signal, measurement conductivity signal, reference temperature signal, measurement In this step, the temperature signal and the current and voltage of the measurement sensor 120 are measured. Subsequently, the amplifying step (S5, S5 ') and the AD conversion step (S6, S6') is a step of converting and amplifying the various signals to convert the analog signal measured to be calculated in the central processing unit into a digital signal.

The calculation steps S7, S8, S7 ', and S8' are performed by the central processing unit 224 using the digital signal to calculate a current, a voltage, a flow rate, and an electric conductivity by using a predetermined calculation expression and a loaded program (S7, S7 ') It is a step to calculate the cleanliness index using this. Furthermore, the calculating step may further include the step of calculating the reference temperature and the measurement temperature (S7 ') and then calculating the heat transfer coefficient, the cleanliness coefficient, and the contamination coefficient (S8') based on the above formula.

The display and storage step (S11, S11) is the external monitor 420 in real time through the touch screen 400 and the external monitor communication unit 240 in real time via the touch screen communication unit 242 various data calculated by the central processing unit 10A to 10B and FIG. 11 to display on the screen, and to store these data in the storage unit 250 at a predetermined time interval.

Figure 10a is a reference temperature (T1), measured temperature (T2), voltage (V), current (A), flow rate (FL), cleanliness index (FI) calculated by the capstone measuring method according to another embodiment of the present invention , The cleanliness factor (FF) and pollution factor (RF) is an example of a touch screen display. As shown in FIG. 10A, the displaying and storing step includes a reference temperature display unit G1, a measurement temperature display unit G2, a measurement sensor voltage display unit G3, a measurement sensor current display unit G4, and a thermal load display unit G5. , Flow rate indicator (G6), cleanliness index indicator (G7), cleanliness coefficient indicator (G8), contamination coefficient indicator (G9), date indicator (G10), resistance indicator (G11) of the reference sensor, resistance indicator ( By displaying the corresponding data in real time using a predetermined program on each display unit of the screen composed of G12), it is possible to grasp the adsorption degree of the capstone in the field in real time so that it is possible to obtain a quick and accurate cleaning time.

10B is an example of a touch screen screen graphically displaying various data measured by a capstone measuring method according to another embodiment of the present invention by day, month, and year. As shown in FIG. 10B, the displaying and storing step includes a daily graph display unit G13, a monthly graph display unit G14, and a yearly graph display unit G15 showing a graph of changes in the cleanliness index for each day, month, and year. At any time, the data stored in the storage unit 250 is imported to the display unit of the screen configured to display the trend of the cleanliness index, cleanliness coefficient or pollution coefficient with a predetermined program so that the cleaning time can be set quickly and accurately. It may further include a graphing step.

As described above, in the present invention, the cleanliness index, the cleanliness coefficient and the contamination coefficient may be calculated and displayed together on the screen, and by comparing these values, the adsorption degree and cleaning cycle of the capstone can be accurately determined. In the heat transfer coefficient method, the change of temperature is affected by the degree of adsorption of the capstone, but when the degree of adsorption reaches a certain degree, the change in temperature does not occur even if the degree of adsorption of the capstone increases, so that the change in the pollution coefficient or the cleanliness coefficient does not occur. Do not. However, in the electrical conductivity method, the conductivity decreases as the degree of adsorption of the capstone increases, so that the cleanliness index continues to drop. Therefore, the manager can accurately evaluate the degree of adsorption of capstone by comparing and analyzing the cleanliness coefficient and the cleanliness index.

According to another embodiment of the present invention, the capstone measuring method of the present invention may further include an external monitor display step. 11 is an example of an external monitor screen displaying various data calculated by the capstone measuring method according to another embodiment of the present invention.

As shown in FIG. 11, the external monitor display step includes a reference temperature display unit C1, a measurement temperature display unit C2, a pollution degree coefficient display unit C3, a heat load display unit C4, a flow rate display unit C5, and a cleanliness index. Display part (C6), measuring sensor voltage display part (C7), measuring sensor current display part (C8), cleanliness index display part (C9), resistance display part (C10) of reference sensor, resistance display part (C11) of measuring sensor, measuring sensor voltage input part Each of the display units C12 and the flow rate input unit C13 may remotely receive and display the corresponding data through the external monitor communication unit 240 as a predetermined program. Here, the measurement sensor voltage input unit C12 is a portion in which the user can directly input a DC voltage to be applied, and when the DC voltage to be applied to the measurement sensor is input, the corresponding signal is converted into DA through the central processing unit 224. The unit 265 is converted into an analog and transmitted to the DC power supply unit, and the DC voltage corresponding to the corresponding amount is applied to the measurement sensor. In addition, the flow rate input unit C13 is a portion for inputting the desired flow rate in order for the user to control the flow rate, and when the user inputs the flow rate, the corresponding signal is converted into an analog signal from the DA converter 260 via the central processing unit 224. It is converted to control the flow control valve 160.

According to another embodiment of the present invention, the capstone measuring method of the present invention, the alarm determination step (S9, S9 ') for determining whether the calculated flow rate exceeds the reference value, and if the alarm determination step result exceeds the reference value relay ( 228) may further include an alarm performing step (S13, S13 ') that performs an alarm by audibly or visually using an alarm unit 430 such as a buzzer or an alarm lamp. At the same time as or after the alarm, the DC power supply unit 5 is controlled via the central processing unit 224 via the DA conversion unit 265 to cut off the power supply of the heater sensor (S15 and S15 '). It may further be provided.

Applicant has described the embodiments of the present invention above, it is obvious that various changes and modifications that implement the technical idea of the present invention also fall within the scope of the present invention.

 The present invention has the following effects by the above configuration.

The present invention can be easily attached or detached to any part of the pipe, so that it is convenient to use in the field, maintenance of devices such as replacement of sensors in the event of sensor failure, and measurement of capstone using electric conductivity, so that flow rate fluctuations and circulation It is not influenced by the temperature change of the fluid, and can check the adsorption degree of capstone in real time through the touch screen not only in the control room but also in the field, and the reference sensor or the measuring sensor can be attached to the pipe, and the sensor configuration The parts are also detachably coupled to each other, so that the capstone attached to the heating electrode of the measuring sensor can be collected without disassembling the device, thereby facilitating the capturing of capstone easily.

In addition, the present invention, in addition to the above object, it is possible to display various data measured or calculated on the touch screen and the external monitor, and has the effect that the basic setting value can be changed using the touch screen without disassembling and assembling the device. .

1 is a block diagram of a capstone measuring apparatus according to an embodiment of the present invention.

Figure 2a is a perspective view of a reference sensor and a measuring sensor according to an embodiment of the present invention.

Figure 2b is an exploded cross-sectional view of the reference sensor and the measurement sensor according to an embodiment of the present invention.

Figure 3a is a cross-sectional view of the coupling of the reference sensor according to an embodiment of the present invention.

Figure 3b is a combined cross-sectional view of the reference sensor according to another embodiment of the present invention.

Figure 4a is a combined cross-sectional view of the measuring sensor according to an embodiment of the present invention.

Figure 3b is a combined cross-sectional view of the measuring sensor according to another embodiment of the present invention.

5 is a view illustrating a process of attaching and detaching a reference sensor and a measuring sensor of the present invention.

6 is a block diagram of a capstone measuring apparatus including a DC power supply unit 5, a sensor unit 10, a circuit unit 20, and a touch screen 400.

Figure 7a is a detailed circuit diagram of the conversion amplifier for measuring and amplifying the sensor signal of the reference sensor and the measurement sensor.

7B shows a PT100Ω sensor circuit.

8 is a flow chart showing a capstone measuring method according to another embodiment of the present invention.

9 is a flowchart showing a capstone measuring method according to another embodiment of the present invention.

Figure 10a is a reference temperature (T1), measurement temperature (T2), voltage (V), current (A), flow rate (FL), cleanliness index calculated by the capstone measuring apparatus and method according to an embodiment of the present invention ( FI), cleanliness factor (FF), contamination factor (RF), resistance (R1), resistance (R2) is an example of a touch screen display.

Figure 10b is an example of a touch screen screen showing a graph of various data calculated by the capstone measuring apparatus and method according to an embodiment of the present invention by day, month, year.

11 is an example of an external monitor screen displaying various data calculated by the capstone measuring apparatus and method according to an embodiment of the present invention.

<Brief description of the main parts of the drawing>

1201: measuring body: 1201a: measuring hole

1201b: Insertion hole, 1201c: Screw hole

1202: Measurement external electrode 1202a: Measurement joint

1202b: Measuring through hole

1202c: screw part

1203: internal electrode of measurement 1203a: screw part

1204: connecting member 1204a: connecting rod

1204b: Bolt ball 1204c: Connecting piece

1203b ': temperature measuring element

Claims (8)

A flow rate control valve connected to the inlet end and controlling a flow rate of the introduced fluid; A reference sensor without a heating wire that measures the electrical conductivity when the capstone is not adsorbed, a measuring sensor with a heating wire that measures the electrical conductivity when the capstone is adsorbed, and a flow measuring sensor that measures the flow rate of the fluid A sensor unit configured to include; A circuit unit for receiving and processing various sensor signals of the sensor unit; An electric conductivity type capstone measuring device comprising a touch screen for receiving various data calculated by the circuit unit and displaying the data on the screen, and changing a basic setting value according to a user's request. The reference sensor of claim 1, wherein the reference sensor comprises: a reference outer electrode having an open reference cavity and one or more reference through holes formed at predetermined intervals along a circumference thereof, and fixing the reference outer electrode; A reference body having a reference center hole in communication with the reference inner electrode, which is inserted into a cavity of the reference outer electrode through the reference center hole of the reference body, The measuring sensor includes a measuring outer electrode having a measuring cavity having an open front end and at least one measuring through-hole formed at predetermined intervals along a circumference thereof, and a measuring center for fixing the measuring outer electrode and communicating with the measuring cavity. A measuring body having a ball and a measuring inner electrode inserted into the cavity of the measuring outer electrode through the measuring center hole of the measuring body, wherein the measuring inner electrode has a heating wire spirally wound therein; The reference sensor and the measuring sensor is provided with a screw thread on the outer circumferential surface of the main body, the conductivity conductivity capstone measuring apparatus, characterized in that the pipe can be attached and detached freely. 3. The electrical conductivity of claim 2, wherein the reference inner electrode and the measurement inner electrode are integrally formed with a temperature measuring element, and the inner electrode, the outer electrode, and the main body of the reference sensor and the measurement sensor can be detachably attached to each other. Anticorrosive capstone measuring device. The method of claim 1, The circuit unit includes an AC power supply unit connected to the measurement sensor and the reference sensor in series to apply AC power, a conversion amplifier unit for receiving and converting the flow signal, the measurement conductivity signal, and the reference conductivity signal from the sensor unit, and amplifying the signal. An analog switch for channel selection and transmission of the signals, an AD converter for converting the sensor signals to AD, a flow rate, electrical conductivity of a reference sensor, electrical conductivity of a measuring sensor, A conductivity measuring capstone measuring apparatus comprising a central processing unit for calculating a cleanliness index and transmitting the displayed cleanness index to the touch screen through a touch screen communication unit, and a storage unit for storing various data. 5. The electroconductive capstone measurement according to claim 4, wherein the circuit unit further includes an external monitor communication unit to transmit the various data and the cleanliness index calculated to the external monitor of the control room using a communication protocol. Device. The AC power supply step of applying a small AC power supply to the reference sensor and the measurement sensor, the reference conductivity signal from the reference sensor, the measurement conductivity signal from the measurement sensor, the flow rate signal from the flow sensor, and the voltage applied to the measurement sensor A measuring step of measuring current, an AD converting step of converting the various signals into an AD converter, and a central processing unit using the converted digital signal according to a predetermined equation, flow rate, electrical conductivity of a reference sensor, and electrical of a measuring sensor. A calculation step of calculating a cleanliness index calculated by dividing conductivity and electrical conductivity of the measuring sensor by the electrical conductivity of the reference sensor; transmitting and displaying the calculated data on a touch screen in real time, and storing these data in real time. Conductivity capstone measuring method comprising the marking and storing step to store in. The method of claim 6, further comprising: an alarm determining step of determining whether the calculated flow rate exceeds a reference value, and an alarm performing step of performing an alarm either audibly or visually when the alarm determination step result is exceeded. Electrical conductivity method capstone measuring method. The method of claim 6, wherein the measuring step includes a step of additionally measuring a reference temperature signal from a reference sensor and a measuring temperature signal from a measuring sensor, wherein the calculating step divides the heat transfer coefficient after a predetermined time by the initial heat transfer coefficient. And a cleanliness factor calculated as a percentage, wherein the displaying and storing steps include a cleanliness index calculated as electrical conductivity of the reference sensor and a measuring sensor, and a cleanliness calculated after the initial heat transfer coefficient and a heat transfer coefficient after a predetermined time. Conductivity measurement capstone measuring method comprising the step of displaying and storing the coefficient together.