JP3679174B2 - Flow compensation device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a flow rate correction device, and more particularly, a flow rate correction device configured to correct a flow rate measurement value measured by a flow meter according to temperature and pressure and to display a numerical value such as a measurement value or a correction value on a display. About.
[0002]
[Prior art]
For example, in the middle of piping for supplying city gas to homes and factories, positive displacement flow meters are installed to measure the supply of city gas (hereinafter referred to as “gas”) as the fluid to be measured. . In this positive displacement flowmeter, a pair of rotors formed in elliptical gears or eyebrows are provided so as to rotate in proportion to the flow rate, so that the rotation number of the rotor is detected by a rotation detection sensor. A pulse with a frequency corresponding to the number of rotations is output. Therefore, the gas supply amount is measured by integrating the number of pulses.
[0003]
However, when measuring the flow rate of a fluid to be measured whose volume changes due to temperature change or pressure change, such as gas, the flow rate measurement value is based on the temperature detected by the temperature sensor and the pressure detected by the pressure sensor. It is necessary to correct the flow rate at the temperature and the reference pressure. Therefore, the flowmeter that measures the flow rate of gas as described above is provided with a flow rate correction device that corrects the flow rate measurement value according to the temperature and pressure at that time.
[0004]
In the conventional flow rate correction apparatus, the temperature data and pressure data detected by the temperature sensor and the pressure sensor are read at predetermined sampling time intervals, and the flow rate measurement value is corrected based on the temperature data and pressure data.
Further, when the flow meter is a field-installed type, the power source uses a battery such as a dry cell. For example, as shown in FIG. A liquid crystal display 3 is provided, and below the liquid crystal display 3 is provided a lid 5 for closing the battery housing 4 (not visible in FIG. 9). The lid 5 is supported by a hinge 5a provided on the right side so that it can be opened and closed. On the front surface of the lid 5, a handle 6 with a key and a push button switch 7 are disposed.
[0005]
A display mode changeover switch (not shown in FIG. 9 is hidden behind the lid 5 and cannot be seen) inside the battery housing 4 to switch the contents of numerical values displayed on the battery (not shown) and the liquid crystal display 3. ) Is arranged. This display mode change switch is composed of a rotary switch, and the display contents of numerical values displayed on the liquid crystal display 3 can be changed according to each rotation angle position. In addition, the function contents (for example, temperature / pressure correction integrated value, non-corrected integrated value, temperature value) when operating at each rotation angle position so that the operator who operates for the first time can understand the operation method are located around the display mode changeover switch. , Pressure values, etc.) are provided.
[0006]
[Problems to be solved by the invention]
In the conventional flow rate correction apparatus, when the display content of the numerical value displayed on the liquid crystal display 3 is switched by operating the display mode changeover switch, the lever of the keyed handle 6 is rotated to cover the battery storage unit 4. After opening 5 and exposing the display mode selector switch, turn the display mode selector switch according to the nameplate indicating the function contents (for example, temperature / pressure correction integrated value, non-correction integrated value, temperature value, pressure value, etc.). Was operating.
[0007]
Here, when no lid 5 of the battery compartment 4, the display mode switch would be arranged on the front surface of the housing 2, also nameplate showing functional content corresponding to the operation position of the display mode switch It will be provided in front of the device. Originally, the numerical value displayed on the liquid crystal display 3 is for confirmation by a staff member entrusted by a gas company in advance, and an unrelated person can display the numerical value and its function content. It is desirable that the display 3 cannot be seen without permission, and that the display switching operation of the liquid crystal display 3 is not allowed.
[0008]
However, the display mode changeover switch to the front face of the housing 2 as described above is provided, if the nameplate function contents are described corresponding to the rotational angular position of the display mode selection switch is disposed on the front surface of the housing 2, the liquid crystal display There is a problem that what kind of function contents are displayed on the device 3 can be understood by a third party who has nothing to do with the nameplate .
Therefore, an object of the present invention is to provide a flow rate correction apparatus that solves the above-described problems.
[0009]
[Means for Solving the Problems]
In order to solve the above problems, the present invention is characterized by the following configuration.
The present invention calculates a reference temperature and a correction value at a reference pressure based on the temperature and pressure detected by the temperature detection means and the pressure detection means, and calculates the reference temperature and the reference temperature from the correction value and the flow measurement value. According to the operation of each operation switch among the correction means for correcting the flow value at the reference pressure, and the numerical values such as the detected value detected by the temperature detecting means and the pressure detecting means and the flow value corrected by the correcting means. In the flow rate correction device having display switching means for displaying the numerical value on the display,
The operation switch is composed of a key switch that is switched by inserting a predetermined key, and a rotary switch for selecting which of the numerical values is displayed on the display.
In the case where a predetermined key is inserted into the key switch and the switching operation is performed, the display switching means displays the numerical value selected by the operation position of the rotary switch and the character indicating the function content of the numerical value. It is characterized by displaying .
[0010]
Therefore, according to the present invention, when a predetermined key is inserted into the key switch and the switching operation is performed, the numerical value selected by the operation position of the rotary switch and the character indicating the functional content of the numerical value are displayed on the display. Because it is displayed, only the operating position of the switch with key and the operating position of the rotary switch and the person who operated it can confirm the numerical value according to the operating position of the rotary switch and the function content on the display, and can confirm it. Furthermore, even if a third party looks at the rotary switch, the function displayed at the operation position is not known, so that it is possible to prevent the rotary switch from being operated mischievously.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a flow rate correction apparatus according to the present invention will be described with reference to the drawings.
FIG. 1 is a front view showing a flow rate correction apparatus, and FIG. 2 is a side view of the flow rate correction apparatus.
The flow rate correction device 11 is provided in the middle of a pipe (not shown) for supplying city gas together with the positive displacement flow meter 12, for example, and is configured to measure the flow rate of the gas flowing in the pipe. The positive displacement flow meter 12 is a Roots positive displacement flow meter having an eyebrows-shaped rotor (not shown) that rotates at a rotational speed proportional to the flow rate, and the reed switch 13 is closed according to the rotation of the rotor. The flow rate pulse is output. The flow path of the positive displacement flow meter 12 is provided with a detection port (not shown) for detecting the pressure of the fluid to be measured, and the flow channel is connected via a pipe line (not shown) connected to the detection port. The pressure is introduced into the pressure sensor 14 inside the flow rate correction device 11. A temperature sensor 15 is provided outside the flow rate correction device 11.
[0012]
The flow rate correction device 11 has a cover 17 screwed to the front surface of a box-shaped housing 16, and faces the liquid crystal display 18 formed of a liquid crystal display (LCD) provided in the housing 16 on the front surface of the cover 17. A display window 19 is provided. Further, on the front surface of the cover 17, a key switch 20 that is operated by inserting a key, a rotary switch 21 that is operated by rotating the lever 21a, and a push button switch 22 that displays the liquid crystal display 18 are displayed. Are arranged. On the periphery of the outer periphery of the rotary switch 21, numbers “0” to “11” are provided as scales so that the rotation operation position can be seen.
[0013]
In the present embodiment, the display of the liquid crystal display 18 cannot be switched even if each of the key switch 20, the rotary switch 21, and the push button switch 22 is operated alone. Thus, it is possible to switch to a predetermined display. That is, a third party who does not have a key for the key switch 20 and does not know the display function by the combination of the switches 20 to 22 does not know how to switch the display of the liquid crystal display 18 by looking at the switches 20 to 22. A third party other than an operator who does not have a key cannot switch the display of the liquid crystal display 18.
[0014]
In this embodiment, when the key switch 20 is in the OFF state, the operation of the rotary switch 21 is invalidated, and when the push button switch 22 is pressed, the temperature pressure correction value is displayed on the liquid crystal display 18. Is done. When the key switch 20 is operated to ON 1, “display mode” is set, and when the key switch 20 is operated to ON 2, “inspection mode” is set.
[0015]
When the rotary switch 21 is rotated in the state where the display mode or the inspection mode is set, the display content corresponding to the rotation operation position of the rotary switch 21 is displayed on the liquid crystal display 18. Further, when the rotary switch 21 is set to the “8” position in the inspection mode state and the push button switch 22 is pressed for 20 seconds or more, the display of the liquid crystal display 18 is reset.
[0016]
A cable 23 drawn from the positive displacement flow meter 12 is connected to the lower surface of the flow rate correction device 11. Therefore, the signal output from the reed switch 13 provided in the positive displacement flow meter 12 is input to the flow rate correction device 11 via the cable 23. Further, a pressure introduction unit 24 to which a pipe (not shown) for supplying the flow path pressure in the positive displacement flow meter 12 to the pressure sensor 14 is connected is provided on the side surface of the flow rate correction device 11. .
[0017]
Therefore, the flow correction device 11 calculates the flow rate by integrating the flow rate pulses output from the reed switch 13 provided in the positive displacement flow meter 12, and from the temperature sensor 15 and the pressure sensor 14 at every predetermined sampling time. Based on the read temperature data and pressure data, temperature correction and pressure correction are performed for the flow rate measurement value.
[0018]
FIG. 3 is a block diagram showing the configuration of the flow rate correction device 11.
The flow rate correction device 11 has a control board 25 mounted in the housing 16. The control board 25 includes a liquid crystal display 18, an A / D converter 26 for pressure circuit that converts pressure detection data output from the pressure sensor 14 into a digital signal, and temperature detection data output from the temperature sensor 15. A / D converter 27 for a temperature circuit for converting the signal into a digital signal, and a control circuit 28 for calculating temperature correction and pressure correction for the flow rate measurement value are provided.
[0019]
Further, in the memory 29 of the control circuit 28, each numerical value such as each measured value output from the reed switch 13, the pressure sensor 14 and the temperature sensor 15 and a calculated calculation value is displayed on the liquid crystal display 18. A control program for displaying the function contents of the numerical values to be displayed on the liquid crystal display 18 is stored.
[0020]
Further, the memory 29 of the control circuit 28 calculates based on the flow rate calculation program for calculating the flow rate by integrating the flow rate pulses, and the temperature and pressure read from the temperature sensor 15 and the pressure sensor 14 every predetermined sampling time. Stored is a temperature / pressure correction program for calculating the temperature / pressure correction of the flow rate measurement value by the temperature / pressure correction coefficient. Therefore, the control circuit 28 executes the temperature / pressure correction processing of the flow rate measurement value based on the flow rate calculation program and the temperature / pressure correction program during flow rate measurement. Then, the control circuit 28 outputs the corrected flow rate measurement value and displays the corrected flow rate measurement value on the liquid crystal display 18.
[0021]
The control board 25 is supplied with power from a battery 30 made of a long-life lithium battery.
Since the gas as the fluid to be measured is a gas, the volume changes by changing the temperature and pressure. The rate of change of the gas volume with respect to the change in temperature and pressure is determined by Boyle-Charles' law. The flow rate correction device 11 calculates a correction coefficient from the temperature / pressure signals output from the temperature sensor 15 and the pressure sensor 14 according to this law, and calculates the volume in the reference state by multiplying the correction coefficient by the flow rate signal.
[0022]
This correction coefficient can be expressed as the following equation (1).
_{K TP = (273.2 + T b} /273.2+T) · (1.033 + P / 1.033+ P b) ... (1)
Here, K _TP is a correction factor for the reference temperature and the reference pressure, T is the gas temperature [° C.], T _b is the reference temperature [° C.], P is the gas pressure [kgf / cm ² G], P _b Is the reference pressure [kgf / cm ² G].
[0023]
Further, when either one of the temperature and the pressure is corrected, the calculation can be performed using one of them as a reference state, which can be expressed by the following equations (2) and (3).
K _T = 273.2 + T _b /273.2+T (2)
K _P = 1.033 + P / 1.033+ P _b (3)
Here, K _T is a correction coefficient for the reference temperature and a correction coefficient for the K _P reference pressure.
[0024]
Here, the flow rate measurement process executed by the control circuit 28 will be described. FIG. 4 is a main flowchart executed by the control circuit 28. 4 is repeatedly executed at predetermined time intervals (for example, every 0.05 msec), and the control circuit 28 sequentially performs temperature / pressure correction according to the temperature / pressure of the fluid to be measured. ing.
[0025]
In step S1 (hereinafter, “step” is omitted), the control circuit 28 uses the pulse signal (rotation detection signal of the rotor rotating in proportion to the flow rate) output from the reed switch 13 as an integer unit of measurement (for example, It is converted into an integer corresponding to liter).
[0026]
Subsequently, the pressure correction coefficient K _P stored in the memory 29 is read (S2). Further, in the next S3, it reads the temperature correction coefficient K _T stored in the memory 29.
Next, the flow rate measurement value converted into an integer measurement unit in S1 is multiplied by the pressure correction coefficient K _P and the temperature correction coefficient K _T obtained in S2 and S3 to calculate the flow rate with respect to the reference temperature and the reference pressure ( S4).
[0027]
In the next S5, the measurement value corrected in S4 is output to an output circuit (not shown) and the liquid crystal display 18.
Thus, since the control circuit 28 corrects the flow rate measurement value by the pressure correction coefficient K _P and the temperature correction coefficient K _T , the flow rate measurement value can be accurately corrected.
[0028]
Next, the display switching process of the liquid crystal display 18 executed by the control circuit 28 of the flow rate correction device 11 which is the main part of the present invention will be described. 5 and 6 are flowcharts of the display switching process executed by the control circuit 28, and FIGS. 7 and 8 show examples of display patterns in the display mode and the inspection mode displayed on the liquid crystal display 18. FIG.
[0029]
When a power switch (not shown) is turned on, the control circuit 28 sets the display on the liquid crystal display 18 to an initial display in step S11 (hereinafter, “step” is omitted). In this initial display, each segment of the liquid crystal display 18 is switched from “0” to “F” for checking. In the next S12, it is determined whether or not the “display mode” is set by operating the key switch 20 to ON 1. When the key switch 20 is not in the “display mode” position, the process proceeds to S13, and when the key switch 20 is operated to ON 2, it is determined whether or not the “inspection mode” is set.
[0030]
In S13, when the “inspection mode” is not set, the process proceeds to S14, and it is determined whether or not the push button switch 22 is pressed. When the push button switch 22 is OFF in S14, the process returns to S12 and the processes of S12 to S14 are executed again. In S14, when the push button switch 22 is on, the process proceeds to S15 to display the temperature / pressure correction value on the liquid crystal display 18. Then, the temperature / pressure correction value is displayed on the liquid crystal display 18 until 5 seconds elapse in S16, and when 5 seconds elapse, the process returns to S12 again and the processes after S12 are executed.
[0031]
If the “inspection mode” is set in S13, the process proceeds to S17 to determine whether or not the rotary switch 21 has been rotated to the position of the scale “8”. If the rotary switch 21 is turned to the position of the scale “8” in S17, the process proceeds to S18, and it is determined whether or not the push button switch 22 has been turned on for 20 seconds or more. If the push button switch 22 is turned on for 20 seconds or more in S18, the process proceeds to S19, where all the integrated values are cleared, and the process proceeds to the initial process (S11) described above.
[0032]
If the rotary switch 21 is not turned to the position of the scale “8” in S17, or if the push button switch 22 is not turned on for 20 seconds or more in S18, the process proceeds to S20 described later.
When the key switch 20 is in the “display mode” position in S12, the process proceeds to S20 and the display mode corresponding to the rotational operation position of the rotary switch 21 is set. In S20, it is determined whether or not the rotary switch 21 has been rotated to the position of the scale “0”. When the rotary switch 21 is in the position of the scale “0”, the process proceeds to S21 and displayed. The mode “temperature / pressure integrated value” (see the display example in FIG. 7) is displayed on the liquid crystal display 18. Thereafter, the process returns to S12 described above.
[0033]
If the rotary switch 21 is not rotated to the position of the scale “0” in S20, the process proceeds to S22 to determine whether the rotary switch 21 is rotated to the position of the scale “1”. judge. When the rotary switch 21 is in the position of the scale “1” in S22, the process proceeds to S23, and the display mode “uncorrected integrated value” (see the display example in FIG. 7) is displayed on the liquid crystal display 18. . Thereafter, the process returns to S12 described above.
[0034]
If the rotary switch 21 is not rotated to the position of the scale “1” in S22, the process proceeds to S24 to determine whether the rotary switch 21 is rotated to the position of the scale “2”. judge. When the rotary switch 21 is in the position of the scale “2” in S24, the process proceeds to S25 and the display mode “temperature value (° C.)” (see the display example in FIG. 7) is displayed on the liquid crystal display 18. Display. Thereafter, the process returns to S12 described above.
[0035]
If the rotary switch 21 is not turned to the scale “2” in S24, the process proceeds to S26 to determine whether the rotary switch 21 is turned to the scale “3”. judge. When the rotary switch 21 is in the position of the scale “3” in S26, the process proceeds to S27 and the display mode “pressure value (MPa)” (see the display example in FIG. 7) is displayed on the liquid crystal display 18. Let Thereafter, the process returns to S12 described above.
[0036]
If the rotary switch 21 is not turned to the scale “3” in S26, the process proceeds to S28 to check whether the rotary switch 21 is turned to the scale “4”. judge. When the rotary switch 21 is in the position of the scale “4” in S28, the process proceeds to S29 and the display mode “pressure value (kgf / cm ² )” (see the display example in FIG. 7) is displayed on the liquid crystal display. 18 is displayed. Thereafter, the process returns to S12 described above.
[0037]
If the rotary switch 21 is not turned to the scale “4” in S28, the process proceeds to S30 to determine whether the rotary switch 21 is turned to the scale “5”. judge. When the rotary switch 21 is in the position of the scale “5” in S30, the process proceeds to S31 to display the “temperature correction integrated value” (refer to the display example in FIG. 7) of the display mode on the liquid crystal display 18. . Thereafter, the process returns to S12 described above.
[0038]
If the rotary switch 21 is not turned to the scale “5” in S30, the process proceeds to S32 to check whether the rotary switch 21 is turned to the scale “6”. judge. When the rotary switch 21 is in the position of the scale “6” in S32, the process proceeds to S33, and the display mode “pressure correction integrated value” (see the display example in FIG. 8) is displayed on the liquid crystal display 18. . Thereafter, the process returns to S12 described above.
[0039]
If the rotary switch 21 is not rotated to the position of the scale “6” in S32, the process proceeds to S34 to check whether the rotary switch 21 is rotated to the position of the scale “7”. judge. When the rotary switch 21 is in the position of the scale “7” in S34, the process proceeds to S35, and the display mode “internal setting code” (see the display example in FIG. 8) is displayed on the liquid crystal display 18. Thereafter, the process returns to S12 described above.
[0040]
If the rotary switch 21 is not turned to the scale “7” in S34, the process proceeds to S36 to determine whether the rotary switch 21 is turned to the scale “8”. judge. If the rotary switch 21 is in the position of the scale “8” in S36, the process proceeds to S18 described above, and it is determined whether or not the push button switch 22 has been turned on for 20 seconds or more. If the push button switch 22 is turned on for 20 seconds or more in S18, the process proceeds to S19, where all the integrated values are cleared, and the process proceeds to the initial process (S11) described above.
[0041]
If the rotary switch 21 is not turned to the scale “8” in S36, the process proceeds to S37 to check whether the rotary switch 21 is turned to the scale “9”. judge. When the rotary switch 21 is in the position of the scale “9” in S37, the process proceeds to S38, and the “last pulse output elapsed time” (refer to the display example in FIG. 8) of the display mode is displayed on the liquid crystal display 18. Let Thereafter, the process returns to S12 described above.
[0042]
If the rotary switch 21 is not turned to the scale “9” in S37, the process proceeds to S39 to check whether the rotary switch 21 is turned to the scale “10”. judge. When the rotary switch 21 is at the scale “10” in S39, the process proceeds to S40 to display “Elapsed time after error occurrence” (refer to the display example in FIG. 8) on the liquid crystal display 18. Let Thereafter, the process returns to S12 described above.
[0043]
If the rotary switch 21 is not turned to the scale “10” in S39, the process proceeds to S41 to determine whether the rotary switch 21 is turned to the scale “11”. judge. When the rotary switch 21 is in the position of the scale “11” in S41, the process proceeds to S42, and the display mode “error code” (see the display example in FIG. 8) is displayed on the liquid crystal display 18. Thereafter, the process returns to S12 described above.
[0044]
If the rotary switch 21 is not turned to the position of the scale “11” in S41, the process proceeds to S43 to determine whether or not the power is off. If the power is off in S43, the series of display control processing ends. However, when the power is on, the process returns to S12 described above, and the processes after S12 are repeated.
[0045]
As described above, the functions that can be displayed on the liquid crystal display 18 can be selectively switched by the combination of the key switch 20 and the rotary operation position of the rotary switch 21, so that the key switch 20 and the rotary switch 21 are provided on the front surface of the cover 17. Even though the push button switch 22 is provided, a third party who does not have the key to be inserted into the key switch 20 cannot arbitrarily switch the display content of the liquid crystal display 18. Can prevent mischief.
[0046]
Further, only the number for identifying the rotation position is described around the rotary switch 21, so it is not known at all in appearance what the rotation position of the rotary switch 21 indicates, and the liquid crystal display 18 The display contents can be recognized only after seeing the display. Therefore, even if a third party looks at the key switch 20, the rotary switch 21, and the push button switch 22 provided on the front surface of the cover 17, the displayed display contents cannot be known.
[0047]
In the above-described embodiment, the positive displacement flow meter 12 in which the eyebrows-shaped rotor is incorporated is taken as an example. However, the present invention is not limited to this. For example, the flow rate measured by a flow meter other than the positive displacement flow meter Of course, the present invention can also be applied to a flow rate correction device that corrects a measurement value.
[0048]
Moreover, in the said Example, although the flow volume correction apparatus 11 was set as the structure integrated in the positive displacement flowmeter 12, it is not restricted to this, For example, the flow volume correction apparatus provided separately from the positive displacement flowmeter 12 is also used. Of course, it can be adapted.
In the above embodiment, the liquid crystal display 18 has been described as displaying data such as the temperature / pressure correction integrated value, the non-correction integrated value, the temperature value, and the pressure value. Of course, the present invention can also be applied to an apparatus having a configuration using a display.
[0049]
【The invention's effect】
As described above, according to the present invention, when a predetermined key is inserted into the key switch and the switching operation is performed, the numerical value selected by the operation position of the rotary switch and the character indicating the function content of the numerical value are displayed. Therefore, only the person who operated the operating position of the keyed switch and the operating position of the rotary switch can confirm the numerical value corresponding to the operating position of the rotary switch and the function content on the display. In addition, even if a third party looks at each switch, the switching method of the display device, the numerical value displayed on the display device, and the function content are not known. Therefore, it is possible to prevent mischief such as arbitrary operation of the rotary switch by a third party, which may be caused by arranging the key switch and the rotary switch on the front surface of the apparatus.
[Brief description of the drawings]
FIG. 1 is a front view of an embodiment of a flow rate correction apparatus according to the present invention.
FIG. 2 is a side view of the flow rate correction apparatus.
FIG. 3 is a block diagram showing a configuration of a flow rate correction apparatus.
FIG. 4 is a flowchart for explaining flow rate measurement processing executed by a control circuit.
FIG. 5 is a flowchart of display switching processing executed by a control circuit.
6 is a flowchart of a display switching process executed subsequent to the process of FIG.
FIG. 7 shows an example of display patterns in a display mode and an inspection mode displayed on a liquid crystal display.
FIG. 8 shows an example of display patterns in a display mode and an inspection mode displayed on a liquid crystal display.
FIG. 9 is a front view of a conventional flow rate correction apparatus.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 11 Flow volume corrector 12 Positive displacement type flow meter 13 Reed switch 14 Pressure sensor 15 Temperature sensor 16 Housing 18 Liquid crystal display 20 Key switch 21 Rotary switch 22 Pushbutton switch 28 Control circuit

Claims (1)

Calculating a correction value at the reference temperature and reference pressure based on the temperature and pressure detected by the temperature detection means and pressure detection means, to correct the with the correction value and the flow rate measurement to the flow rate value at the reference temperature and reference pressure Among the numerical values such as the correction means, the detection value detected by the temperature detection means and the pressure detection means, and the flow rate value corrected by the correction means , a numerical value corresponding to the operation of each operation switch is displayed on the display. In a flow correction device having a display switching means ,
The operation switch is composed of a key switch that is switched by inserting a predetermined key, and a rotary switch for selecting which of the numerical values is displayed on the display.
In the case where a predetermined key is inserted into the key switch and the switching operation is performed, the display switching means displays the numerical value selected by the operation position of the rotary switch and the character indicating the function content of the numerical value. A flow rate correction device characterized by displaying on the screen .

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