JPH0473500A - Seawater flow control method in lng vaporizer - Google Patents

Abstract

PURPOSE:To operate an LNG vaporizer with a minimum necessary a flowrate of seawater, and reduce power consumption by applying the constitution wherein tube outlet temperature and seawater temperature are measured, using an optical fiber, and a seawater flowrate control device at a seawater feed passage is controlled, according to the result of the measurement. CONSTITUTION:A seawater flowrate control means 12 is equipped with an optical fiber distribution type measurement device comprising a measurement device body 14 and optical fibers 15 as sensors. The optical fibers 15 are arranged at all outlets of the tube 4 of a vaporizer panel 5 for an LNG vaporizer 1, and at suitable positions of a seawater feed passage 7. The constitution is so made that the seawater flowrate control means 12 gives the predetermined seawater flowrate on the basis of temperature at all outlets of the tube 4 of the vaporizer 5 and seawater temperature detected with the aforesaid sensors, and sets the flowrate in the controller 12 of a seawater flowrate control device 9. According to the aforesaid construction, the LNG vaporizer 1 can be operated with a minimum necessary flowrate of seawater throughout the year, and power consumption for seawater pump operation can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a seawater flow rate control method in an LNG vaporizer.

(Prior Art) In an oven rack vaporizer, which is an LNG vaporizer that uses seawater as a heating source, the seawater temperature changes depending on the season, so conventionally, the flow rate of seawater supplied to the LNG vaporizer is The operator can set a sufficient amount by considering the safety factor based on the seawater temperature, or the LNG
The temperature of the gas in the gas header pipe of the vaporizer is measured and the temperature is set based on this measured temperature.

On the other hand, if the flow rate of seawater is insufficient for the LNG load, the vaporization panels will gradually ice up, and if left unattended, the inconvenience of low-temperature liquid flowing into the room-temperature piping will occur.To prevent these inconveniences from occurring, Conventionally, workers monitor the condition of the vaporizer panels by patrolling, or monitor the temperature of the gas in the gas header pipe.

(Problems to be Solved by the Invention) As described above, the flow rate of seawater set by the operator based on the temperature of the seawater is an amount with a sufficient margin in consideration of the safety factor. Also, when setting the flow rate based on the temperature of the gas in the gas header tube, the gas temperature at this position is the average temperature of the gases from each tube of the vaporization panel mixed together. Therefore, if there is insufficient flow of seawater in a part of the vaporization panel and ice has formed,
There is a large time delay until this is detected, so the flow rate of seawater set using this method must also be set to a sufficient amount. In this way, conventionally, no matter which method is applied, seawater is supplied at a sufficient amount, which consumes more electricity than necessary to operate the seawater pump. .

On the other hand, regarding monitoring for insufficient flow of seawater, monitoring by patrols by workers is limited in monitoring frequency, making continuous monitoring practically impossible, and it is difficult to always respond promptly to the occurrence of abnormalities. In addition to being difficult, there are individual differences in determining abnormalities, and there is also a risk of overlooking abnormalities. Furthermore, in monitoring the temperature of the gas in the gas header pipe, there is a large time delay until detection as described above, so it is still difficult to take prompt action.

The present invention aims to solve the above problems by rationally utilizing an optical fiber distributed temperature measuring device known as a distributed temperature measuring device.

(Means for Solving the Problems) In order to solve the above problems, the seawater flow rate control method in the LNG vaporizer of the present invention first uses an optical fiber as a sensor of an optical fiber distributed temperature measuring device. were installed corresponding to all of the tube outlet sides of the vaporization panel in the LNG vaporizer to be monitored, and the average value of the temperature measurements on the outlet side of these tubes was measured using an appropriate temperature sensor. Based on the seawater temperature, a seawater flow rate control device installed in the seawater supply path to the LNG vaporizer is controlled.

In addition, the seawater flow rate control method in an LNG vaporizer of the present invention is such that an optical fiber as a sensor of an optical fiber distribution type temperature measuring device is connected to all of the outlet side of the tube of the vaporization panel in the LNG vaporizer to be monitored. and a seawater flow rate control device installed in the seawater supply path based on the average value of temperature measurements on the outlet side of the plurality of tubes and the seawater temperature. be.

In the above configuration, if the temperature measurements on the outlet sides of multiple tubes are uneven, the seawater flow rate in the seawater supply route is controlled in accordance with the lowest value of the temperature measurements on the outlet sides. It is something.

(Function) In the present invention described above, in the LNG vaporizer to be monitored, all temperatures on the outlet side of the tube of the vaporization panel and their change trends can be constantly measured. For this reason,
If the temperature distribution on these outlet sides is within a predetermined uniform range, that is, the temperature distribution of the evaporation panel is uniform, the average value of these outlet side temperature measurements and an appropriate temperature sensor are used. The required amount of seawater can be set based on the average value and the temperature of the seawater, and this set value can be changed in accordance with the average value and fluctuations in the seawater temperature. By controlling the seawater flow rate control device provided in the seawater supply route using this set value, the LNG vaporizer can be operated with the minimum required flow rate of seawater throughout the year.

During such operation, if the temperature on the outlet side of the tube partially decreases and the temperature distribution on the outlet side falls outside the predetermined uniform range, the temperature on these outlet sides will decrease. The required amount of seawater is set from the lowest measured value and the temperature of the seawater. For this reason, seawater is supplied at a flow rate corresponding to the part of the vaporization panel where the flow rate is insufficient, and the operation is performed in a direction that eliminates the lack of flow rate.

On the other hand, a partial drop in temperature on the outlet side of the tube is considered to be due to a break in the seawater curtain in the vaporization panel, so an alarm is issued by the seawater flow rate control means that operates as described above. , workers can inspect the LNG vaporizer and perform predetermined processing quickly.

(Example) Next, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is an explanatory diagram showing the configuration of the present invention, where the symbol l is LN.
G vaporizer, that is, an open rack type vaporizer.

As is well known, this open rack type vaporizer is constructed by continuously arranging tubes 4 with fins between an upper gas header pipe 2 and a lower liquid header pipe 3 to form a vaporizer panel 5.
The structure is such that seawater flows down uniformly in a curtain-like manner on both sides of the vaporization panel 5 through seawater troughs 6 formed at the top.

Reference numeral 7 is a seawater supply path for supplying seawater to the seawater trough 6, 8 is a seawater pump, and 9 is a seawater flow rate control device comprising an orifice 10, a flow rate control valve 11, and a controller 12.

Reference numeral 12 denotes a seawater flow rate control means.The seawater flow rate control means 12 is provided with an optical fiber distributed temperature measuring device known as a distributed temperature measuring device. This measuring device consists of a measuring device main body 14 and an optical fiber 15 as a sensor. This optical fiber distributed temperature measurement device uses the phenomenon that the intensity of backscattered light of laser pulse light propagating in an optical fiber changes depending on the temperature of the optical fiber, and measures the temperature around the optical fiber. It is measured in a distributional manner.

In the LNG vaporizer 1 to be monitored, the optical fiber 15 as the sensor is connected to the entire outlet side of the tube 4 of the vaporization panel 5 and to a suitable location of the seawater supply path 7, for example, inside the seawater trough 6. I have it installed. Then, the flow rate control means 12 derives a predetermined seawater flow rate based on all the temperatures on the outlet side of the tube 4 of the vaporization panel 5 and the seawater temperature detected by these sensors, and sets this as the seawater flow rate. The configuration is such that it is set in the controller 12 of the control device 9. Instead of measuring the temperature of the seawater using the optical fiber distribution type temperature measuring device described above, the temperature of the seawater may be measured using another suitable temperature sensor 16, as shown by the phantom line in FIG. Further, in the embodiment shown in FIG. 2, the optical fiber 15 is installed so that a predetermined length portion thereof is brought into contact with the periphery of the exit side of the tube 4 by a sheet 17 having good thermal conductivity. However, the method of installing the optical fiber 15 is arbitrary. In addition, the optical fiber 15 can be installed in series to correspond to a predetermined plurality of LNG vaporizers l. If corresponding installation is not possible, by configuring multiple systems via a switch, a common measuring device body can perform temperature measurements corresponding to all of the large number of LNG vaporizers to be measured.

In the above configuration, the seawater flow rate control means 13 controls the tube 4 of the vaporization panel 5, which is identified by the main body 14 of the optical fiber distributed temperature measuring device, according to the distance from the reference position along the optical fiber 15. The temperature on the exit side of the seawater, as well as the temperature of the seawater, and their changing trends are constantly measured.

Therefore, if the temperature distribution on the outlet side measured in this way is within a predetermined uniform range, it is considered that the temperature distribution of the vaporization panel 5 is uniform and the operating state is normal.
In this case, the required amount of seawater is derived from the average value of these outlet-side temperature measurements and the temperature of the seawater, and is set in the controller 12 of the seawater flow rate control device 9. This set value is changed in accordance with the above-mentioned average value and fluctuations in seawater temperature, and by controlling the seawater flow rate control device 9 installed in the seawater supply route 7 using this set value, the minimum necessary amount is maintained throughout the year. The LNG vaporizer 1 can be operated with a flow rate of seawater.

During such operation, if the temperature on the outlet side of the tube 4 partially decreases and the temperature distribution on the outlet side deviates from a predetermined uniform range, the seawater flow rate control means 1
3 derives the required amount of seawater from the lowest value of these temperature measurements on the outlet side and the temperature of the seawater, and sets it in the controller 12 of the seawater flow rate control device 9. In this way, by controlling the seawater flow rate control device 9 using this set value, seawater is supplied at a flow rate corresponding to the portion of the vaporization panel 5 where the flow rate is insufficient, and operation is performed in a direction to eliminate the flow shortage.

On the other hand, such a partial drop in temperature on the outlet side of the tube 4 is considered to be due to a break in the seawater curtain in the vaporization panel 5, so the seawater flow rate control means 13
will issue an appropriate warning. Therefore, the worker can receive the above-mentioned warning, check the water sprinkling state of the seawater trough 6 of the relevant LNG vaporizer 1, etc., and quickly perform the prescribed treatment.

(Effects of the Invention) As described above, the present invention measures all the temperatures on the outlet side of the tube of the vaporization panel of the LNG vaporizer to be monitored by rationally utilizing the optical fiber distributed temperature measuring device. Since the flow rate of seawater flowing into the seawater supply route is set based on this measured value and the seawater temperature measured appropriately, the LNG vaporizer can be operated with the minimum flow rate of seawater throughout the year, and the seawater pump can be operated throughout the year. This has the effect of reducing the amount of power consumed to operate the system. Furthermore, by measuring all the temperatures on the outlet side of the tube, the present invention can continuously and automatically monitor the lack of seawater flow rate, which enables early detection and quick response. There is no problem of individual differences in judgment or oversight,
This has the effect of improving reliability.

[Brief explanation of the drawing]

Figure 1 is a system explanatory diagram showing the configuration of the present invention, Figure 2 (a
) and (b) are enlarged explanatory views of main parts showing an example of the installation state of optical fibers. Code l: LNG vaporizer, 2: gas header pipe,
3... Liquid header pipe, 4... Tube, 5... Vaporization panel, 6... Seawater trough, 7... Seawater supply route, End... Seawater pump, 9... Seawater flow rate control device , 10
...orifice, 11...flow control valve, 12...
Controller, 13...Seawater flow rate control means, 14...Optical fiber distributed temperature measuring device main body, 15...Optical fiber,
16... Temperature sensor, 17... Sheet. Figure 1

Claims (5)

[Claims] (1) Optical fibers as sensors of the optical fiber distributed temperature measuring device are installed in correspondence with all the outlet sides of the tubes of the vaporization panel in the LNG vaporizer to be monitored,
A seawater flow rate control device provided in the seawater supply path to the LNG vaporizer is controlled based on the average value of temperature measurements on the outlet side of these tubes and the seawater temperature measured by an appropriate temperature sensor. Seawater flow rate control method in LNG vaporizer (2) In the LNG vaporizer to be monitored, install the optical fiber as a sensor of the optical fiber distributed temperature measurement device so that it corresponds to all the tube exit sides of the vaporization panel and the appropriate location of the seawater supply route. A seawater flow rate control method in an LNG vaporizer, characterized in that a seawater flow rate control device provided in the seawater supply path is controlled based on the average value of temperature measurements on the outlet side of the plurality of tubes and the seawater temperature. (3) In the method of claim 1 or claim 2, if the temperature measurements on the outlet sides of the plurality of tubes are uneven, seawater is A seawater flow rate control method in an LNG vaporizer, characterized by controlling the seawater flow rate in a supply route. (4) The optical fiber according to claim 1 or 2 is characterized in that a predetermined length of the optical fiber is installed in contact with the periphery of the exit side of the tube using a sheet with good thermal conductivity. Flow rate control method (5) The optical fiber according to claim 2 is characterized in that a common optical fiber is installed in correspondence with all the outlet sides of the tubes of the vaporization panel and at appropriate locations in the seawater supply route. Control method