JPH0775087A - Method for monitoring carburetor panel - Google Patents

Abstract

PURPOSE:To solve the subject of a conventional carburetor panel monitoring method using an infrared ray camera or the like. CONSTITUTION:The adfreezing height(h) of a carburetor panel 5 to be monitored is obtained from the corresponding relation of an LNG flow rate, sea water temperature, and trickling flow rate, the temperature distribution of the horizontal direction of the carburetor panel 5 at the height or near the height is measured from infrared ray radiation, a temperature difference between a mean temperature and a lowest temperature, or between a highest temperature and the mean value is measured, and those values are compared with a set value, so that abnormality can be discriminated. Thus, the channelling of the sea water at the carburetor panel 5 and the overall decrease of the trickling flow rate can be automatically discriminated, those abnormalities can be early detected, and the deformation of the carburetor panel 5 or the like resulting in those abnormalities can be prevented. At the time of the automatic discrimination, a complicate picture input and the processing can be unnecessitated, and the automatic discrimination can be operated based on the measured of one- dimensional temperature distribution. Thus, the high speed processing can be attained by a device which is simpler than heretofore.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for monitoring a carburetor panel such as an open rack vaporizer, and more particularly to a method for monitoring a decrease in sprinkling flow rate and seawater drift.

[0002]

2. Description of the Related Art In an open rack vaporizer, which is an LNG vaporizer that uses seawater as a heating source, if uneven distribution of seawater occurs on the vaporizer panel, the temperature distribution on the vaporizer panel becomes non-uniform and the icing height increases. However, there is a risk that imbalance will occur and stress that will cause deformation of the carburetor panel will occur.

Therefore, conventionally, there are a method in which an operator patrols and monitors, a temperature sensor is installed in a proper place for monitoring, and a vaporizer panel is photographed by an infrared camera and monitored by a temperature image. For a monitoring method using an infrared camera, see, for example, Japanese Patent Laid-Open No. 4-77599.

In the conventional monitoring method using such an infrared camera, the above-mentioned abnormality is detected by the pattern of the temperature image of the carburetor panel, and an alarm or a control signal is generated based on the detected abnormality. .

[0005]

The method of detecting an abnormality by the pattern of the temperature image of the carburetor panel as described above has the following problems. Since a high-performance image processing apparatus is indispensable, the cost is high and the processing time is long. Since the pattern of a normal temperature image changes according to operating conditions such as a change in seawater temperature and a change in LNG flow rate depending on the season, the image processing apparatus is provided with a reference pattern for detecting an abnormality. It is necessary to have a plurality according to operating conditions. Even if the above condition is satisfied, the seawater drift in the carburetor panel cannot be automatically determined. It is an object of the present invention to solve the problems of the conventional monitoring method using such an infrared camera.

[0006]

In order to solve the above-mentioned problems, in the present invention, first, the icing height in the carburetor panel to be monitored is determined from the correspondence relationship between the LNG flow rate, the seawater temperature and the sprinkling flow rate. At the same time, the temperature distribution in the lateral direction of the carburetor panel at or near this height is measured by infrared radiation to obtain the temperature difference between the minimum temperature and the maximum temperature or average temperature, and this value is compared with the set value for abnormalities. We propose a method of monitoring a carburetor panel that determines

Further, in the present invention, the ice accretion height in the carburetor panel to be monitored is determined from the correspondence relationship between the LNG flow rate, the seawater temperature and the sprinkling flow rate, and the lateral direction of the carburetor panel at or near this height. We propose a method for monitoring the carburetor panel that measures the temperature distribution of infrared rays by measuring the average temperature by infrared radiation and compares this value with a set value to determine anomalies.

Further, in the present invention, the ice accretion height on the carburetor panel to be monitored is determined from the correspondence relationship between the LNG flow rate, the seawater temperature and the sprinkling flow rate, and the carburetor panel lateral direction at or near this height. The temperature distribution of the carburetor panel is measured by measuring the temperature distribution by infrared radiation and measuring the temperature difference between the average temperature and the minimum temperature and the maximum temperature or the average temperature, and comparing these values with the set value to determine an abnormality. To propose.

[0009]

The ice accretion height on the carburetor panel has a correspondence relationship with the LNG flow rate, the seawater temperature and the sprinkling flow rate, and these correspondence relationships can be obtained by measurement in advance. Therefore, if such a correspondence relationship is stored in advance, the icing height can be estimated from the LNG flow rate, seawater temperature, and sprinkling flow rate measured at the time of monitoring.

In the carburetor panel, the upper edge portion of the ice accretion, that is, the portion corresponding to the ice accretion height and the vicinity thereof is most susceptible to the change of the sprinkling flow rate, and the change rate of the temperature with respect to the change of the sprinkling flow rate is the most. The largest. Therefore, the distribution of the water spray flow rate in the lateral direction of the vaporizer panel can be measured with the highest sensitivity by the lateral temperature distribution of the vaporizer panel at or near the ice height. The temperature distribution in the lateral direction of the carburetor panel at or near the ice accretion height can be easily measured by infrared radiation.

The point where the lowest temperature is observed in the measured lateral temperature distribution of the carburetor panel corresponds to the point where the local reduction of the sprinkling flow rate due to the drift occurs, and the temperature difference with other points is the drift. Indicates the degree. In addition, the decrease in average temperature indicates the overall decrease in water flow rate.

Therefore, the temperature difference between the lowest temperature and other points,
For example, by obtaining a temperature difference between the lowest temperature and the highest temperature or the average temperature, and comparing this with a set value, it is possible to automatically determine a drift current of a predetermined value or more. Similarly, by comparing the average temperature with the set value, it is possible to automatically determine a decrease in the overall sprinkling flow rate above a predetermined value.

[0013]

Embodiments of the present invention will now be described with reference to the drawings.
FIG. 1 shows an overall configuration of an apparatus to which the method of the present invention is applied. Reference numeral 1 denotes a vaporizer, that is, an open rack type vaporizer. This open rack type vaporizer is known as an upper header. A carburetor panel 5 is constructed by continuously arranging tubes 4 having fins between the pipe 2 and the lower header pipe 3, and seawater is supplied from seawater troughs 6 formed on both side surfaces of the upper part of the carburetor panel 5. LN flowing down from the lower header pipe 3 evenly in a curtain shape
This is a configuration for vaporizing G. Reference numeral 7 is a seawater supply line to the seawater trough 6, and the seawater supply line 7 is provided with a flow rate measuring means 8 and a temperature measuring means 9. On the other hand, reference numeral 10 is an LNG supply line, and the LNG supply line 10 is provided with a flow rate measuring means 12 downstream of the control valve 11.

Reference numeral 13 is a radiation temperature measuring means for measuring the temperature of a proper place within the monitoring range of the vaporizer panel 5 by infrared radiation, and the radiation temperature measuring means 13 is composed of an infrared camera and a radiation thermometer. In the figure, the radiation temperature measuring means 13 is installed on the front side of the carburetor panel 5, but it can also be installed diagonally.

Reference numeral 14 is a processing means. The processing means 14 receives signals from the flow rate measuring means 8 and 12 and the temperature measuring means 9 as an input signal, and as will be described later, an assumed ice accretion height of the carburetor panel 5. Then, h is obtained, and the radiation temperature distribution in the lateral direction of the vaporizer panel 5 is measured by the radiation temperature measuring means 13 at this height h. When an abnormality is determined based on the result of processing the measured value in a predetermined manner, the alarm means 15 is operated, or the control means 16 causes the control valve 1 to operate.
1 is a safe operation.

FIGS. 3 to 8 show how the temperature of seawater flowing on the surface of the carburetor panel 5 at the same height changes with changes in the sprinkling flow rate, and the sprinkling flow rate is 10%.
The results of measuring the height of icing at 0% are shown.
That is, Fig. 3 shows that the inlet seawater temperature is 25 ° C and the LNG flow rate (flow rate) is 60.
In the condition of%, it shows the result of execution when the sprinkling flow rate was changed from 100% to 50%, and the icing height h was 0.09 m when the sprinkling flow rate was 100%. Similarly, Fig. 4 shows the results of implementation when the sprinkling flow rate was changed from 100% to 50% under the condition of the inlet seawater temperature of 25 ° C and the LNG flow rate (flow rate) of 80%. The ice height h at the time is 0.19 m
Met. In addition, Fig. 5 shows the sprinkling flow rate of 100% to 50% under the condition of the inlet seawater temperature of 25 ° C and the LNG flow rate (flow rate) of 100%.
It shows the result of implementation when the water flow rate is changed to
The icing height h at 100% was 0.215 m. In addition, Figure 6 shows the results of implementation when the sprinkling flow rate was changed from 100% to 50% under the conditions of the inlet seawater temperature of 8 ° C and the LNG flow rate (flow rate) of 60%. Icing height h
Was 0.67 m. Figure 7 shows the inlet seawater temperature of 8 ° C and LN.
G flow rate (flow rate) is 80%, and sprinkling flow rate is 100%.
This shows the results of implementation when the water flow rate was changed to -50%, and the icing height h was 1.05 m when the water flow rate was 100%. In addition, Figure 8 shows the results of implementation when the sprinkling flow rate was changed from 100% to 50% under the conditions of an inlet seawater temperature of 8 ° C and an LNG flow rate (load) of 100%. The icing height h was 1.466 m.

As shown in these figures, the temperature of seawater flowing on the surface of the portion of the carburetor panel 5 is most easily affected by the change in the sprinkling flow rate at a portion near the icing height h at a sprinkling flow rate of 100%, and the sprinkling water is sprinkled. It can be seen that the ratio of temperature change to flow rate change is the largest. Therefore, the distribution of the water flow rate in the lateral direction of the vaporizer panel 5 is 100%.
It can be seen that the most sensitive measurement can be made by the lateral temperature distribution of the carburetor panel 5 at or near the location corresponding to the ice accretion height h in FIG.

FIG. 9 is a summary of the results of the implementation of FIGS. 3 to 8 described above for the icing height h. In this figure, when the sprinkling flow rate is 100%, the incoming seawater temperature is used as a parameter, and the LNG flow rate is set. It is shown as the correspondence of the change in the icing height h to the change in.

9 and the above-described FIGS. 3 to 8, the ice accretion height h in the carburetor panel 5 is determined by the LNG flow rate,
It shows that there is a correspondence relationship with the incoming seawater temperature and the sprinkling flow rate, and these correspondence relationships can be obtained by pre-measurement.

For example, by storing a plurality of correspondences as shown in FIG. 9 using the sprinkling flow rate as a parameter, the correspondences between the LNG flow rate, the incoming seawater temperature and the sprinkling flow rate, and the icing height h are stored. be able to. The processing means 14 stores such correspondence in the form of an approximate expression or a data table and performs the following processing.

First, the processing means 14 includes the above-mentioned means 8, 9,
From the sprinkling flow rate, seawater temperature, and LNG flow rate measured in accordance with 12, the expected ice accretion height h is obtained from the stored correspondence relationship. Then, the processing means 14 measures the temperature distribution in the lateral direction of the carburetor panel 5 by the radiation temperature measuring means 13 in correspondence with the height h thus obtained. The measurement vertical width at each position thus measured can be appropriately set in consideration of an error, for example, about 10 cm.

The rectangular frame 17 in FIG. 2 schematically shows the monitoring range of the carburetor panel 5, and the solid line in the figure shows the measured temperature distribution. In this measurement result, the temperature at the location a is lower than that at other locations, and the local water flow rate is reduced at this location a due to drift, and the temperature difference with other locations indicates the degree of drift. .

Therefore, the processing means 14 obtains the minimum temperature, that is, the temperature difference ΔT between the temperature at the location a and the maximum temperature T ₀ , compares this with a preset set value ΔTs, and if it is larger than this, Is determined to be abnormal, and predetermined processing,
For example, the control valve 11 is controlled by the sounding of the alarm means 15 and the operation of the control means 16. In this way, the set value ΔTs for determining an abnormality of the uneven flow is, for example, the difference between the temperature at the sprinkling flow rate of 100% and the temperature at the sprinkling flow rate of 80%. In this case, the reduction of the sprinkling flow rate due to uneven flow is allowed up to 80%,
It indicates that the abnormality is not judged. Of course, the set value Δ
Ts can be higher or lower. The temperature difference ΔT may be the temperature difference between the lowest temperature point a and the highest temperature T ₀ as described above, or may be the difference between the lowest temperature point a and the average temperature T described later. .

That is, the processing means 14 is, in addition to the above processing,
An average temperature T of the measured temperature distribution is obtained and compared with a preset set value Ts. A decrease in the average temperature T indicates a general decrease in the water spray flow rate, and the lower the average temperature T, the lower the water spray flow rate. Therefore, when the average temperature T is lower than the set value Ts, the processing means 14 determines that there is an abnormality and performs the above-described processing at the time of abnormality. In this way, the set value Ts for determining the decrease in the overall sprinkling flow rate can be set to the temperature at the sprinkling flow rate of 80%, for example. In this case, the overall reduction in sprinkling flow is 20%
Indicates that it will not be judged as abnormal. Of course, the set value Ts can also be made higher or lower.

[0025]

As described above, the present invention has the following effects as compared with the conventional carburetor panel monitoring method using an infrared camera that detects an abnormality based on a temperature pattern or an absolute value of temperature. is there. Along with the drift of seawater in the carburetor panel, it is possible to automatically determine the decrease in the overall sprinkling flow rate. Therefore, by detecting these abnormalities at an early stage, deformation of the carburetor panel due to such abnormalities can be prevented. Can be prevented. Since automatic image determination can be performed based on the measurement of one-dimensional temperature distribution without complicated image input and processing, it is possible to perform high-speed processing with a simpler device than before.

[Brief description of drawings]

FIG. 1 is a system diagram showing an overall configuration of an apparatus to which the present invention is applied.

FIG. 2 is an explanatory diagram schematically showing an example of temperature distribution measured by applying the present invention.

[Fig. 3] It is measured how the temperature of seawater flowing on the surface of the vaporizer panel at the same height changes with the change of the sprinkling flow rate, and the icing height when the sprinkling flow rate is 100% is measured. It shows the measured results.

[Fig. 4] Under other conditions, it was measured how the temperature of seawater flowing on the surface of the vaporizer panel at the same height changes with changes in the sprinkling flow rate, and the sprinkling flow rate was 100%.
The result of measuring the height of icing when% is shown.

FIG. 5 shows how the temperature of seawater flowing on the surface of the vaporizer panel at the same height changes in response to changes in the sprinkling flow rate under other conditions.
The result of measuring the height of icing at 100% is shown.

FIG. 6 shows how the temperature of seawater flowing over the surface of the vaporizer panel at the same height changes in response to changes in the sprinkling flow rate under other conditions.
The result of measuring the height of icing at 100% is shown.

FIG. 7 is a graph showing how the temperature of seawater flowing on the surface of the carburetor panel at the same height changes in response to changes in the sprinkling flow rate under other conditions.
The result of measuring the height of icing at 100% is shown.

FIG. 8 shows how the temperature of seawater flowing over the surface of the carburetor panel at the same height changes in response to changes in the sprinkling flow rate under other conditions, and the sprinkling flow rate is measured.
The result of measuring the height of icing at 100% is shown.

FIG. 9 shows the results of the implementation of FIGS. 3 to 8 collectively for the icing height h.

[Explanation of symbols]

1 vaporizer (open rack type vaporizer) 2 upper header pipe 3 lower header pipe 4 tube 5 vaporizer panel 6 seawater trough 7 seawater supply line 8 flow measuring means 9 temperature measuring means 10 LNG supply line 11 control valve 12 flow measuring means 13 Radiation temperature measuring means 14 Processing means 15 Warning means 16 Control means

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Masahiro Arakawa 4-8-3 Old works in Funabashi City, Chiba Prefecture (72) Inventor Ichiro Kasama 1-19-16 Kitasuna, Koto-ku, Tokyo (72) Inventor Kazumi Onui Kanagawa 9-10 Misonodai, Fujisawa, Japan (72) Inventor Takayoshi Yamamoto 2-6-2 Otemachi, Chiyoda-ku, Tokyo Within Babcock Hitachi, Ltd. (72) Inventor Shigeru Kamada 2-6 Otemachi, Chiyoda-ku, Tokyo -2 At Babcock Hitachi, Ltd. (72) Inventor Tatsuo Yoshioka 4-6 Kanda Surugadai, Chiyoda-ku, Tokyo Inside Hitachi, Ltd.

Claims (3)

[Claims] 1. The ice accretion height on a carburetor panel to be monitored is determined from the correspondence relationship with the LNG flow rate, seawater temperature and sprinkling flow rate, and the temperature distribution in the lateral direction of the carburetor panel at or near this height. A method for monitoring a carburetor panel characterized by determining the temperature difference between the lowest temperature and the highest temperature or the average temperature by measuring the infrared radiation and comparing this value with a set value to determine an abnormality 2. The ice accretion height on the carburetor panel to be monitored is determined from the correspondence relationship with the LNG flow rate, seawater temperature and sprinkling flow rate, and the temperature distribution in the lateral direction of the carburetor panel at or near this height. The method for monitoring the carburetor panel is characterized by determining the average temperature by measuring the infrared radiation and comparing this value with a set value to determine an abnormality. 3. The icing height on the carburetor panel to be monitored is determined from the correspondence relationship between the LNG flow rate, seawater temperature and sprinkling flow rate, and the temperature distribution in the lateral direction of the carburetor panel at or near this height. Is measured by infrared radiation, the average temperature and the temperature difference between the minimum temperature and the maximum temperature or the average temperature are measured, and an abnormality is determined by comparing these values with a set value. Monitoring method