JPH09292269A - Flow measuring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a measuring device which can be easily fitted to an existing fluid flowing line and is simple in construction by providing a pulse generator generating a pulse signal corresponding to control valves in an electrified state and a computer computing the fluid flow based on this. SOLUTION: This flow measuring device is constituted of a pulse generator 21 detecting the electrified state of control valves 5a, 5b and outputting a fixed pulse signal corresponding to fuel flow flowing in a fuel feed line 3 by the control valves 5a, 5b in the open state, and a computer 23 computing the evaporated quantity of a boiler 1. Further it is provided with an analog-digital converter 22 converting a pressure detected signal from a pressure sensor 12 to a digital signal, and a data transmitter 24 transmitting the digital signal from the A/D converter 22 and the pulse signal from the pulse generator 21 to the computer 23. Thereby, the vapor flow self-evaporated by change of vapor pressure is corrected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluid flow line formed by connecting control valves for controlling the flow of fluid,
The present invention relates to an apparatus for measuring the flow rate of fluid in a fluid flow line by detecting the energized state of the control valve.

[0002]

BACKGROUND OF THE INVENTION Measuring the flow rate of fluids is necessary for controlling and managing equipment. For example, in a boiler, the boiler is controlled by measuring various flow rates such as the fuel supply amount, the water supply amount, and the steam generation amount, and the combustion amount, boiler efficiency, etc. are obtained based on these flow rates. As a result, the usage status is reliably grasped and management for efficient operation is performed. Usually, in the management of such a boiler, each of the above-mentioned amounts is recorded in a diary (usually referred to as a boiler diary), and after the end of the operation, the feed water flow rate, the fuel flow rate, and the like for each fixed time (for example, 1 hour) From the record, the load condition of the boiler, that is, the steam consumption is calculated. However, in this calculation method, the steam usage is calculated based on each measurement value for every fixed time, and therefore, only the average value of the steam usage during this fixed time is obtained. By the way, in general, steam usage fluctuates over time as shown in Fig. 2. Therefore, when adding or updating (replacement) the boiler, it is necessary to know the instantaneous steam usage (maximum steam usage) and the temporal load change tendency. If desired, an accurate value cannot be obtained by the above-mentioned analysis method using the average value. In order to detect the steam load including such an instantaneous maximum value, for example, it is possible to attach a steam flow meter to the steam pipe of the boiler and measure the amount of steam used by the boiler. However, such a steam flow meter is generally expensive, and
Since there is no problem even if it is not normally provided, there are generally few places where each boiler is connected. In addition, adding a new steam flow meter requires labor and cost. Further, depending on the boiler, the fuel flow meter and the feed water flow meter are not always connected, and adding a fuel flow meter or a feed water flow meter to such a boiler is also a trouble. And it costs money.

[0003]

SUMMARY OF THE INVENTION Therefore, the problem to be solved by the present invention is to provide a flow rate measuring device having a simple structure, which can be easily attached to an existing fluid flow line to measure a fluid flow rate. Further, it is an object of the present invention to provide a steam flow rate measuring device having a simple structure, which can be easily attached to an existing boiler to measure the steam flow rate.

[0004]

The present invention provides a control valve in the energized state by detecting the energized state of the control valve in a fluid flow line formed by connecting a control valve for controlling the flow of fluid. The above-mentioned problems are solved by a flow rate measuring device characterized by comprising a pulse generator that generates a corresponding pulse signal and a calculator that calculates a fluid flow rate based on this pulse signal.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention is embodied as a flow rate measuring device for measuring a fluid flow rate in a fluid flow line formed by connecting a control valve for controlling fluid flow. This flow rate measuring device is composed of the pulse generator and an arithmetic unit, detects whether the control valve is in the energized state by the pulse generator, and if there is a control valve in the energized state, the corresponding control is performed. A pulse signal corresponding to the valve is generated, and the fluid flow rate is calculated in the calculator based on the pulse signal. That is, since the flow rate of the fluid (per unit time) is determined by the open state of each control valve in the fluid flow line, the fluid flow rate per unit time can be determined by detecting whether each control valve is in the energized state. You can ask. Here, the energized state of the control valve means that electric power for driving the control valve is being supplied. That is, in the case where the control valve is a solenoid valve or a motor-operated valve (motor valve) that simply turns on and off, by using the terminal on the control valve side or the power supply side to detect the presence or absence of energization, It is possible to determine whether the control valve is open or closed.
In addition, the control valve changes the applied voltage value or current value,
In the case of a servo valve whose opening can be adjusted, the valve opening rate can be determined by detecting the applied voltage value and current value in the same manner as described above. Further, since the flow rate measuring device of the present invention measures the flow rate based on the energized state of the control valve in the fluid distribution line, at least in the existing (or existing) fluid distribution line, at least the control valve is used. If provided, the fluid flow rate can be determined by connecting a pulse generator to this control valve.

The fluid flow line has a control valve for opening and closing the flow passage in one flow passage, or controls the valve opening rate for adjusting the flow rate in the flow passage in one flow passage. In addition to those provided with a control valve, all fluid flow lines provided with a control valve are included, such as those provided with a plurality of branch passages and provided with a control valve that selectively opens and closes each of the branch passages.

The pulse generator is connected to the control valve, detects the energized state, and generates a pulse signal corresponding to the energized control valve. The pulse signal at this time is
Depending on the number of control valves that have been energized to open or closed, and the number of pulses per unit time corresponding to the flow rate of fluid passing through each control valve, the width and height of each pulse ( Amplitude). For example, when the control valve is a solenoid valve that turns on and off the flow path, the flow rate through the control valve is determined by the operating state of the control valve (whether the valve is open or closed). Is detected, a pulse signal corresponding to the flow rate of the fluid flowing through the fluid supply line is output. In such a control valve, there are those that open the flow passage and those that close the flow passage by supplying electric power. In this case, in the pulse generator or the arithmetic unit, the correspondence between the flow rate and the pulse signal is determined. You can reverse it. Here, when the fluid flow line includes one control valve, the pulse generator outputs the above-mentioned pulse signal corresponding to the energized state of the one control valve, but includes a plurality of control valves. In this case, a pulse signal is output corresponding to the number of control valves that have been opened (or closed). When the flow rate of fluid passing through each control valve is the same, the flow rate of fluid flowing through the fluid supply line is proportional to the number of control valves in the open state.
If there is a difference in the flow rate of fluid passing through each control valve, the pulse signal is adjusted according to the ratio. This pulse generator generates a pulse signal unique to each well-known oscillator circuit whose time constant changes according to an external signal, and the energization state of each control valve, and calculates these pulse signals. In addition to the hardware configuration such as the one using an arithmetic circuit for generating a pulse signal corresponding to the control valve in the energized state, the control signal for the energized state of each of the control valves is processed by a predetermined process. It includes one configured by incorporating software for generating a pulse signal together with an appropriate arithmetic processing device.

The calculator has a function of storing the procedure for obtaining the fluid flow rate from the pulse signal from the pulse generator as software (program) and recording the calculation result of the fluid flow rate as data. In addition to being configured as a dedicated processing device that performs only processing, the above procedure is stored in a general-purpose processing device. In the latter case, for example, a stationary type, a portable type, a portable type personal computer, a workstation, etc. are included.
The pulse signal input to this arithmetic unit is converted into data that can be processed by this arithmetic unit after being generated by the pulse generator and before being processed by software by the arithmetic unit.

As described above, the control valve in the fluid distribution line to which the present invention is applied is particularly applied to a fluid supply line in which the fluid flow rate is adjusted stepwise by using the control valve that performs only the opening / closing operation. Although suitable, it can also be applied to a fluid supply line equipped with a control valve for continuously adjusting the fluid flow rate.

Further, the flow rate measuring device of the present invention can be implemented as a device for measuring the fuel supply amount of a boiler by applying a fuel supply line for supplying fuel to the boiler as a fluid supply line, and also as a boiler. It can also be implemented as a steam flow rate measuring device for analyzing the steam load in. Here, this steam load is the amount of steam used in this system when viewed from the entire system in which steam-using equipment is connected to the boiler.If only the boiler is focused on, it corresponds to the amount of steam generated and both It means the flow rate of steam in the steam pipe. When the flow rate measuring device of the present invention is implemented as a steam flow rate measuring device, in a boiler equipped with a control valve for controlling the supply of fuel to a fuel supply line as a fluid flow line, the energized state of the control valve is detected. Thus, the steam flow rate is calculated based on the fuel flow rate obtained in the above procedure. That is, the evaporation amount of the boiler has a correlation with the amount of heat generated by the combustion of the fuel, so that the evaporation amount can be obtained by detecting the supply amount of the fuel.

As is well known, the fuel supply line is for supplying fuel to a combustion device of a boiler, and the flow rate measuring device detects an energized state of a control valve connected in the fuel supply line. To do.

Similarly to the above, the computing unit has a function of storing the procedure for obtaining the evaporation amount from the fuel flow rate corresponding to the pulse signal as software (program) and recording the calculation result of the evaporation amount as data. so,
In the same manner as described above, in addition to being configured as a dedicated processing device that performs only the above processing, the above procedure is stored in a general-purpose processing device.

Further, the steam flow measuring device is configured to correct the steam flow rate by inputting a steam pressure detection signal from a pressure detecting means provided in the boiler. That is, if the pressure inside the boiler can changes during combustion, the amount of evaporation changes due to this pressure change.If the steam pressure inside the boiler can decreases during combustion, in addition to the evaporation corresponding to the amount of combustion Since vaporization (so-called self-evaporation) occurs due to this reduced pressure state, the vapor amount is corrected by inputting the pressure inside the boiler can and adding the vapor amount due to this self-evaporation. On the other hand, when the steam pressure in the boiler can rises during combustion, the enthalpy of the water content of the boiler corresponding to this pressure increase increases from the combustion amount, so the heat amount corresponding to this increase is The steam amount is corrected by subtracting it from the combustion amount to calculate the steam amount.

The boiler to which the present invention is applied is applied to the one in which the combustion amount is adjusted stepwise by using the control valve that only performs the opening / closing operation, such as the two-position control, the three-position control, and the four-position control. However, the present invention is also applicable to the proportional control using the control valve that continuously adjusts the fuel flow rate as described above.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment in which the flow rate measuring device according to the present invention is implemented as a steam flow rate device for analyzing the steam load of a boiler will be described with reference to the drawings. 1. FIG. 1 is a schematic explanatory view showing the configuration of one embodiment of the fluid measuring device according to the present invention.

First, an example of a boiler to which the steam flow rate measuring apparatus in this embodiment is applied will be described with reference to FIG. In FIG. 1, a boiler 1 has a combustion device 2 attached to the upper part thereof, and the combustion device 2 includes a fuel supply line 3 and a wind box 4 which is a supply path of combustion air.

The combustion device 2 in this embodiment is of a type in which the amount of combustion is adjusted stepwise, and in the illustrated embodiment, it corresponds to a three-position control system. That is,
Since the combustion amount is adjusted in three stages of stop, low combustion, and high combustion, the fuel supply line 3 is provided with two branch pipes 3a, 3b, and each of the branch pipes 3a, 3b The control valves 5a and 5b are connected to each of them. Then, the supply amount of fuel is adjusted stepwise by selectively opening and closing the control valves 5a and 5b. The control valves 5a and 5b in this embodiment are normally-closed solenoid valves, which open the flow path when energized. Further, an air supply means (not shown) such as a blower is attached to the upstream end of the wind box 4, and the supply amount of the combustion air from this air supply means depends on the adjustment of the charge supply amount. Adjusted in stages. Incidentally, the supply amount of the combustion air is adjusted by a method of providing an air volume adjusting damper on the downstream side of the air adjusting means, a method of controlling the number of revolutions of the blower by an inverter or the like.

A water supply line 6 is connected to the boiler 1, and a water supply pump 8 and a check valve 9 are connected to the water supply line 6 from the upstream side thereof. Further, a steam line 10 for taking out steam generated inside is connected to the boiler 1, and a main steam valve 11 is inserted in the steam line 10. Further, the boiler 1 is provided with a pressure sensor 12 as pressure detecting means for detecting the pressure inside the can.

Now, the vapor flow rate measuring device 2 according to the present invention
0 is a control valve 5a, 5 connected to the fuel supply line 3
By detecting the energized state of b, the fuel flow rate corresponding to the number of control valves in the valve open state is calculated, and the vapor flow rate is calculated based on this fuel flow rate. Further, in the present invention, in order to accurately detect the steam flow rate, a pressure detection signal from the pressure sensor 12 is input to a calculator, and the calculator detects the fuel flow rate and the pressure in the boiler can. Based on this, the steam flow rate is obtained. In detail, the steam flow measuring device 20 detects the energization state of the control valves 5a and 5b, and a predetermined amount corresponding to the fuel flow rate flowing through the fuel supply line 3 by the control valves 5a and 5b which are in the open state. The pulse generator 21 outputs the pulse signal of 1 and the calculator 23 that calculates the evaporation amount of the boiler 1 from the pulse signal. Further, an analog-digital converter (hereinafter referred to as A / D) that converts the pressure detection signal (analog signal) from the pressure sensor 12 into a digital signal.
It is called a D converter. ) 22, and the A / D converter 22
The data transmitter 24 for transmitting the digital signal from the pulse generator 21 and the pulse signal from the pulse generator 21 to the calculator 23.

The pulse generator 21 includes the control valve 5
Based on the energized states of a and 5b, the control valves 5a and 5b are opened to generate a pulse signal corresponding to the fuel flow rate in the fuel supply line 3. Since the control valve in this embodiment is a normally-closed type solenoid valve, the control valve side or the power supply side terminal and the input terminal of the pulse generator 21 are connected to each control valve 5a, 5b. The presence or absence of electricity is detected. In this way, the power supply terminals of the control valves 5a and 5b are connected to the pulse generator 2 when the control valves 5a and 5b are in the energized state.
Since it can be detected by connecting to the control circuit of the boiler 1, there is no need for modification such as connecting a detection terminal to the control circuit of the boiler 1, and even if the pulse generator 21 is connected to the power supply terminal, the control circuit of the boiler or The fuel flow rate and the steam flow rate can be detected without affecting the operation of the control valves 5a and 5b. Furthermore, in this embodiment, two control valves 5a,
Since the combustion amount is switched between high combustion and low combustion by selectively controlling the opening and closing of 5b, if the combustion amount of high combustion is twice that of low combustion, in the case of a high combustion state,
The number of pulses generated per fixed time is twice that in the low combustion state. For example, when only one of the control valves 5a and 5b is in the energized state and the fuel supply state is in the low combustion state, a pulse is generated once every two seconds and both The control valves 5a and 5b are in the energized state,
When the fuel supply state is in the high combustion state, pulses are generated once per second. The pulse generator 21 is, for example, a well-known oscillation circuit whose time constant changes according to an external signal, and detects the energization state of each of the control valves 5a and 5b by a relay or the like, and the time constant is determined by this relay contact. A predetermined pulse signal is generated from the timer circuit by changing the resistance value, the capacitance of the capacitor, and the value of the inductance to be determined. Further, the pulse generator 21 generates a unique pulse signal according to the energization state of each control valve 5a, 5b,
The pulse signals corresponding to the control valves 5a and 5b in the energized state may be generated by calculating these pulse signals. As described above, the pulse generator 21
In addition to using a well-known oscillator circuit or an arithmetic circuit to be configured only by hardware, it is also configured by incorporating software for performing an arithmetic process according to the energization state of the control valves 5a and 5b together with an appropriate arithmetic processing device. It may be one.

The A / D converter 22 is for converting an analog signal from the pressure sensor 12 into a digital signal as described later.

The data transmitter 24 functions as an interface for collectively transmitting the pulse signals from the pulse generator 21 and the A / D converter 22 to the arithmetic unit 23. In this embodiment, , The arithmetic unit 2
3 and the pulse generator 21 and the A / D converter 22. When a general personal computer is used as the computing unit 23 as in this embodiment, the RS-232C standard serial interface is used as a standard for this personal computer.
The data transmitter 24 also uses a serial interface of the same standard, and by connecting to the interface on the side of the arithmetic unit 23, the pulse generator 21 is connected.
And the signal from the A / D converter 22 in one operation
Send to In this embodiment, the A / D converter 2
The output signal from 2 is a digital signal, while the output signal from the pulse generator 21 is a pulse signal. Therefore, in order to transmit these signals to the arithmetic unit 23 by the data transfer unit 24, it is necessary to convert the pulse signal from the pulse generator 21 into a digital signal. To this end, for example, a counter circuit that counts the number of pulses and outputs a digital signal is built in the A / D converter 22 or the data transmitter 24, or is connected between the two. Further, in this embodiment, the signal from the A / D converter 22 and the signal from the pulse generator 21 are collectively transmitted to the arithmetic unit 23 via the data transmitter 24. However, the function as this interface is to use the A / D converter 22 and the pulse generator 21.
May be incorporated into the pulse generator 21 or A
The pulse signal from the / D converter 22 may be directly input to the arithmetic unit 23.

The arithmetic unit 23 includes the control valves 5a and 5b.
Which has a function of obtaining the fuel flow rate from the pulse signal indicating the energization state of the fuel cell and storing the calculation procedure for obtaining the evaporation amount based on the fuel flow rate as software (program) and recording the calculation result of the evaporation amount as data. In this embodiment, therefore, a portable personal computer is used for the purpose of easily attaching it to the existing boiler 1 and analyzing the steam load. It should be noted that the calculator 23 has a value specific to the boiler for analyzing the steam load, such as the amount of water and efficiency of the boiler, the feed water temperature, and the control valves 5.
The flow rate of the fuel passing through a and 5b, the specific weight of the fuel, the calorific value of the fuel, etc. are input as preset values and stored. In addition, saturated water, an enthalpy value of saturated steam, and the like according to the temperature and pressure of steam are also input and stored in the calculator 23 as reference data. Then, the fuel flow rate is obtained from the pulse signal, the fuel flow rate passing through each of the control valves 5a and 5b, and the specific weight of the fuel. Further, the fuel flow rate and the steam load obtained from these set values have a predetermined time width. It is calculated accordingly. By sequentially writing this calculation result together with the date and time into a storage device (not shown) of the computing unit 23 and referring to this calculation result later and totaling it, it is possible to grasp the operating condition of the boiler 1 over time. .

Further, the steam flow measuring device 20 of the present invention
Basically, the evaporation amount is analyzed by the fuel supply amount. Further, in the present invention, the calculation signal of the pressure inside the can from the pressure sensor 12 that detects the pressure inside the can of the boiler 1 is calculated. The steam flow rate is corrected by inputting it to the vessel 23. That is, when the steam pressure in the boiler can decreases during combustion, in addition to the evaporation corresponding to the combustion amount, evaporation due to this decrease in pressure (so-called self-evaporation)
Therefore, the steam amount is corrected by inputting the pressure in the boiler can and adding the steam amount by this self-evaporation. On the other hand, when the steam pressure in the boiler can rises during combustion, the enthalpy of the water content of the boiler corresponding to this pressure increase increases, so the heat quantity corresponding to this increase is subtracted from the combustion quantity to calculate the steam quantity. Correct the amount of steam by calculating The pressure detection signal from the pressure sensor 12 at this time is converted into a pulse signal (digital signal) by the A / D converter 22, and the data transmitter 24
It is input to the arithmetic unit 23 via.

Next, a method for calculating the steam load, that is, the steam usage amount, based on the obtained data will be described.
The calculation method of the steam consumption is based on the data of fuel flow rate and steam pressure. At this time, it is appropriate that the data sampling time be about 10 seconds. As described above, the fuel flow rate is proportional from the pulse signal based on the energization state of each control valve 5a, 5b based on the value of the fuel flow rate flowing when each control valve 5a, 5b is in the open state. Since it can be calculated, detailed description is omitted.

(1) When the steam pressure inside the can is constant, when the steam pressure inside the can is constant, the heat quantity of the heat input is entirely consumed for steam generation. kg / cm ² G Boiler efficiency: 90% Water temperature: 20 ℃ Fuel flow rate: 0.19 liter / 10 sec Specific weight of fuel: 0.86 g / cm ³ Calorific value of fuel: 10200 kcal / h ・ kg , [Heat input amount] = [fuel flow rate] x [fuel specific gravity] x [fuel heat generation amount] = 0.19 x 0.86 x 10200 = 1667 [kcal]. The heat input is used for the energy of evaporation, and the enthalpy of the feed water (enthalpy of saturated water at a water temperature of 20 ° C) is 20.03 kcal / kg and the vapor pressure is 5 kg / cm ² G
Since the enthalpy of saturated steam is 657.99 kcal / kg, [steam amount] = [heat input amount] × [boiler efficiency] ÷ [increased enthalpy] = 1667 × 0.90 ÷ (657.99-20.03) = 2.35 [ kg].

(2) When the vapor pressure in the can is decreasing When the vapor pressure in the can is decreasing, the amount of self-evaporation is added. The pressure inside the can is 5.4 kg / cm ² during the sampling time.
If G → 4.6 kg / cm ² G, the amount of water in the can is reduced to 2
00kg, other conditions are the same as above. Letting χkg be the amount of self-evaporation in which water inside the boiler can evaporates due to pressure changes, the enthalpy of saturated steam when the steam pressure inside the can is 5.4 kg / cm ² G is 658.64 kcal / kg, and the enthalpy of saturated water is , 162.174 kcal / kg, the total heat in the boiler can at this time is 162.174 × 200 [kcal]. On the other hand, when the steam pressure in the can is 4.6 kg / cm ² G, the enthalpy of saturated steam is 657.28 kcal / kg and the enthalpy of saturated water is 156.810 kcal / kg. The calorific value is ((200−χ) × 156.810 + χ × 657.990) [kcal]. In the case of this self-evaporation, since there is no heat exchange, the total amount of heat before and after the change in the pressure in the can is the same, and the following equation 162.174 x 200 = (200-x) x 156.810 + x x 657.99 holds. Therefore, solving this equation, the self-evaporation amount χ
Is χ = 2.14 [kg] Therefore, the total amount of steam is 2.35 + 2.14 = 4.49 [kg].

(3) When the steam pressure in the can rises When the steam pressure in the can increases, the calorific value necessary for increasing the enthalpy corresponding to the amount of water held in the boiler 1 is subtracted from the calculation. The pressure inside the can is 4.6 → 5.4 kg / cm during the sampling time.
^In case of ² G, other conditions are the same as above, (162.174 -156.810) × 200 = 1072.8 [kcal] 1072.8 ÷ 657.99 = 1.63 [kg] Therefore, the steam amount is 2.35-1.63 = 0.72 [kg]. kg] The steam flow rate is calculated as described above, but a correction coefficient is appropriately used in consideration of the type of boiler, operating conditions, etc.

The data of the steam flow rate obtained as described above is stored in the arithmetic unit 23 and is output and confirmed as necessary. Further, based on the data, a more detailed boiler is obtained. Analyze the load situation of. In particular, by storing this data in the arithmetic unit 23 together with the date and time, it becomes possible to grasp the change (or tendency) of the steam load with time. Further, as described above, the calculation of the steam load is performed based on the pulse signal generated according to the control valve in the energized state, so that the instantaneous steam usage amount can also be detected.

A boiler to which the present invention is applied gradually changes the amount of combustion by using a control valve such as a solenoid valve that only performs opening / closing operations, such as two-position control, three-position control, and four-position control. Although it is particularly suitable for application to adjustment, it can also be applied to proportional control using a control valve such as a flow control valve that continuously adjusts the fuel flow rate. Further, in the present invention, a water supply temperature detecting means for detecting the water supply temperature is connected to the water supply line 6, and the data of the water temperature detected by the water temperature detecting means is used in the same manner as the pressure sensor 12 to change the A / D converter 22. , Data transmitter 2
Alternatively, it may be configured so as to be input to the arithmetic unit 23 via No. 4. That is, in the calculator 23, the supply water temperature is not used as a fixed value as described above but as a change amount, and the above calculation is performed to correct the steam flow rate.
A more accurate value can be obtained.

[0031]

As described above, according to the flow rate measuring device of the present invention, the flow rate of the fluid in the fluid flow line can be
A configuration in which the energized state of a control valve that controls the flow of fluid is detected, a pulse signal corresponding to the energized state of the control valve is generated, and the fluid flow rate is calculated based on this pulse signal for measurement. Therefore, even if it is an existing fluid flow line, as long as it has a control valve, it is possible to easily connect the flow measuring device of the present invention to the control valve without newly connecting a flow meter. The fluid flow rate can be measured.

Furthermore, the flow rate measuring device according to the present invention can be applied to a fluid distribution line (fuel supply line) for supplying fuel to a boiler and can be used as a device for measuring the fuel supply amount of a boiler. It can also be implemented as a steam flow measuring device for analyzing the steam load in a boiler. In this case, the steam usage (steam flow) per minute time of the boiler can be easily measured, and the maximum steam usage Accurate values can be easily measured. Further, by detecting the pressure in the boiler can and correcting the evaporation amount based on the combustion amount by this pressure, it is possible to measure the accurate steam flow rate in consideration of the change in the steam pressure. Moreover, since at least the measuring device is connected to the control valve of the fluid supply line (fuel supply line) to detect the open / closed state of the control valve, the structure is simple, the cost is low, and the existing boiler is easy. Can be connected to perform vapor load analysis.

[Brief description of drawings]

FIG. 1 is a schematic explanatory diagram showing a configuration of an embodiment of a fluid measuring device according to the present invention.

FIG. 2 is a graph showing a time variation of a general steam load in a boiler.

[Explanation of Codes] 1 Boiler 2 Combustion device 3 Fuel supply line (fluid distribution line) 5a Control valve 5b Control valve 6 Water supply line 12 Pressure sensor (pressure detection means) 20 Steam flow rate measurement device (flow rate measurement device) 21 Pulse converter 22 A / D converter 23 Arithmetic unit 24 Data transmitter

Claims (3)

[Claims] 1. Control valves 5a, 5b for controlling the flow of fluid.
A pulse generator 21 for generating a pulse signal corresponding to the energized control valves 5a and 5b by detecting the energized state of the control valves 5a and 5b in a fluid flow line 3 formed by connecting A flow rate measuring device comprising a calculator 23 for calculating a fluid flow rate based on a pulse signal. 2. The fluid distribution line 3 is for supplying fuel to the boiler 1, and the computing unit 23 is
2. The flow rate measuring device according to claim 1, wherein the vapor flow rate is obtained based on the fuel flow rate obtained from the pulse signal corresponding to the energization state of the control valves 5a and 5b. 3. The flow rate measurement according to claim 2, wherein the calculator 23 corrects the steam flow rate based on a steam pressure detection signal obtained by a pressure detection means 12 provided in the boiler 1. apparatus.