JP3769771B2 - How to return the natural gas to the tank when adjusting the calorific value - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a gas supply facility in which liquefied natural gas LNG discharged from an LNG tank is vaporized by a vaporizer and then shipped after adjusting the amount of heat. In order to avoid this, the present invention relates to a method for returning the vaporized natural gas to the tank at the time of adjusting the calorific value of the natural gas used when the vaporized natural gas is temporarily returned to the LNG tank.
[0002]
[Prior art]
As this kind of conventional gas supply equipment, as schematically shown in FIG. 4, a vaporizer 2 is connected to a lower position of the LNG tank 1 by a pipe 3, and the liquefied natural gas LNG in the LNG tank 1 is pumped by a pump 4. The liquefied natural gas LNG guided to the vaporizer 2 is discharged through the pipe 3, and the flow rate of the liquefied natural gas LNG guided to the vaporizer 2 is measured by the flow meter 5 in the middle of the pipe 3. By adjusting the flow rate, the flow rate is controlled. Further, when the liquefied natural gas LNG is vaporized into the natural gas NG by the vaporizer 2, the natural gas NG is guided to the heat quantity adjusting unit 9 by the gas supply pipe 8, while A gas having a constant calorific value higher than that of the gas, for example, a heat increasing gas 10 such as LPG, and a gas having a constant calorific value lower than that of natural gas or a zero calorific value, for example, a dilution gas 11 such as air. There are some which are supplied through the pipes 12 and 13 and mixed with the natural gas NG to adjust the calorific value of the natural gas NG, and then shipped from the supply pipe 14 to the customer.
[0003]
When the carburetor 2 is started in a gas supply facility that is shipped after the liquefied natural gas LNG is vaporized by the vaporizer 2 and then the calorific value is adjusted by the calorific value adjusting unit 9, the automatic open / close valve 15 in the middle of the pipe 3 is used. , The pump 4 is started and the liquefied natural gas LNG in the LNG tank 1 is sent to the carburetor 2 while controlling the flow rate by the flow rate control valve 7, but the carburetor 2 is started and the liquefied natural gas is started. When LNG is vaporized into natural gas NG, the composition of the vaporized natural gas NG may fluctuate and the calorific value adjustment of the natural gas NG in the calorific value adjustment unit 9 may be disturbed.
[0004]
Therefore, conventionally, in order to return the natural gas NG to the LNG tank after the start of vaporization until the calorific value of the vaporized natural gas NG is stabilized in order to avoid such a state, a check valve of the gas supply pipe 8 is used. The upstream position of 16 and the LNG tank 1 are connected by a vaporized gas return pipe 17, and a pressure control valve 18 and an automatic opening / closing valve 21 are provided in the middle of the vaporized gas return pipe 17. 8 is measured by a pressure gauge 19 and adjusted by a pressure controller 20, and the automatic open / close valve 21 is opened so that the natural gas NG is temporarily returned to the LNG tank 1.
[0005]
[Problems to be solved by the invention]
However, when the conventional natural gas NG is temporarily returned to the LNG tank 1, the vaporized natural gas NG is returned to the LNG tank 1 at room temperature, which causes the following problems. That is, the natural gas NG contains heavy components such as propane, butane, and pentane, which are components of the liquefied natural gas LNG, while the evaporated gas (BOG: main component is methane) in the LNG tank 1. Since the natural gas NG is returned to the LNG tank 1 and mixed with the evaporating gas, the natural gas NG is cooled by the evaporating gas and the heavy components in the natural gas are liquefied and become mist. Since natural gas containing mist is mixed with evaporative gas, mist may be generated in the evaporative gas. When mist is generated in the evaporative gas, the mist is condensed in the process of evaporating the gas leaving the LNG tank 1 and being sucked into the BOG compressor, draining in the middle of the pipe, or clogging the suction filter of the BOG compressor There is a problem that.
[0006]
Therefore, the present invention liquefies the heavy components in the natural gas that cause mist generation when returning the natural gas to the LNG tank, dissolves it in the liquefied natural gas LNG, and dissolves it in the evaporated gas in the LNG tank. It is intended to prevent the generation of mist.
[0007]
[Means for Solving the Problems]
In order to solve the above problems, the present invention vaporizes liquefied natural gas discharged from an LNG tank with a vaporizer, and returns the natural gas to the LNG tank temporarily when adjusting the calorific value of the vaporized natural gas. In the method, the vaporized gas return pipe for returning the natural gas to the LNG tank is provided with a mixer, and the liquefied natural gas pipe is connected to the vaporized gas return pipe at the upstream side of the mixer to return the natural gas to the returned natural gas. A predetermined amount of liquefied natural gas is mixed and mixed, and a heavy component in the natural gas is liquefied and dissolved in the liquefied natural gas, and then returned to the LNG tank.
[0008]
Further, about 30% of liquefied natural gas may be mixed with the amount of natural gas returned to the LNG tank through the natural gas return pipe to liquefy only heavy components in the natural gas.
[0009]
Furthermore, in the natural gas return method in which the liquefied natural gas discharged from the LNG tank is vaporized by a vaporizer and the natural gas is temporarily returned to the LNG tank when the calorific value of the vaporized natural gas is adjusted, the vaporized gas return pipe is It is inserted into the liquid layer in the LNG tank and cooled by blowing the returned natural gas directly into the liquid layer in the LNG tank, and the heavy components in the natural gas are liquefied to enter the liquid layer. It can also be set as the method of making it melt | dissolve.
[0010]
[Action]
When the liquefied natural gas is mixed with the vaporized gas that is being returned to the LNG tank, and the heavy components that cause mist are dissolved in the liquefied natural gas and returned to the LNG tank, the vaporized gas in the LNG tank Mist generation can be suppressed.
[0011]
Moreover, when the amount of liquefied natural gas is mixed with the amount of natural gas as about 30%, only heavy components in the natural gas can be liquefied.
[0012]
Further, when the vaporized gas is blown back into the liquid layer of the LNG tank, the heavy components in the vaporized gas are dissolved in the liquid layer of the LNG tank, and mist generation in the evaporated gas can be suppressed.
[0013]
【Example】
Embodiments of the present invention will be described below with reference to the drawings.
[0014]
FIG. 1 shows an embodiment of the present invention. In the configuration similar to the method for returning the natural gas to the tank shown in FIG. 4, the automatic open / close valve 21 of the vaporized gas return pipe 17 and the LNG tank are shown. The mixer 22 is installed at a position between the liquefied natural gas pipe 23 and the liquefied natural gas pipe 23 connected to the upstream position of the mixer 22, and the liquefied natural gas LNG guided from the liquefied natural gas pipe 23 is The gas is introduced into the natural gas NG that is being returned to the LNG tank 1 through the vaporized gas return pipe 17, and the natural gas NG and the liquefied natural gas LNG are mixed by the mixer 22 to cool the natural gas, thereby liquefying the natural gas. A heavy component (propane, butane, pentane, etc.) which is a component of natural gas is liquefied and dissolved (absorbed) in the liquefied natural gas, and then returned to the LNG tank 1. Other configurations are the same as those shown in FIG. 4, and the same components are denoted by the same reference numerals.
[0015]
The liquefied natural gas pipe 23 connected to the vaporized gas return pipe 17 is connected to a liquefied natural gas pipe (not shown) having a cooling operation valve on the upstream side, and the liquefied natural gas is connected to the liquefied natural gas pipe 23. The liquefied natural gas is liquefied natural gas piping 23 by flowing the liquefied natural gas, or by joining the upstream side to a liquefied natural gas piping (not shown) connected to a tank in which liquefied natural gas always flows. To make it flow.
[0016]
Now, when the vaporizer 2 is started to vaporize the liquefied natural gas LNG, and the calorific value of the vaporized natural gas NG is adjusted by the calorific value adjusting unit 9, the natural gas NG is temporarily sent from the vaporized gas return pipe 17 to the LNG tank 1. When a predetermined amount of liquefied natural gas LNG flows through the liquefied natural gas pipe 23 and is mixed with the natural gas NG by the mixer 22 when returning to the natural gas NG, the natural gas NG is brought into the vaporized gas return pipe 17. Is cooled, and the heavy components in the natural gas NG are liquefied and dissolved in the liquefied natural gas LNG. In this state, the mixed fluid of the natural gas NG and the liquefied natural gas LNG is returned from the vaporized gas return pipe 17 into the LNG tank 1.
[0017]
Of the mixed fluid of the natural gas NG and the liquefied natural gas LNG returned to the LNG tank 1, the natural gas NG becomes the same main component gas as the evaporated gas BOG in the LNG tank 1, and is mixed into the evaporated gas. However, since the heavy component is not contained in the natural gas NG returned to the LNG tank 1, no mist is generated in the evaporated gas. On the other hand, the liquefied natural gas LNG that has absorbed the heavy components liquefied by the cooling of the natural gas NG enters the liquid layer in the LNG tank 1 and is discharged to the vaporizer 2 by the pump 4.
[0018]
In the above, in order to cool the natural gas NG returned from the vaporized gas return pipe 17 into the LNG tank 1 and selectively liquefy only the heavy components, a predetermined amount of liquefied natural gas LNG is required. In the present invention, about 30% of the liquefied natural gas LNG is mixed with the amount of the natural gas NG returned to the LNG tank 1 so that only the heavy components in the natural gas NG are liquefied.
[0019]
The reason why the amount of the liquefied natural gas LNG is about 30% of the natural gas NG amount is as follows.
[0020]
That is, the natural gas NG, which is a vaporized gas of the liquefied natural gas LNG, varies depending on its component, but when it is cooled from room temperature to about −50 ° C., liquefaction partially begins (dew point temperature).
[0021]
When the cooling temperature is further lowered below this temperature, the amount of liquefaction further increases. In this case, the degree of liquefaction is determined by the cooling temperature.
[0022]
Here, the cooling temperature is set to a temperature that is lower by −30 ° C. than the dew point temperature (−50 ° C.), that is, −80 ° C.
[0023]
The cooling heat quantity q is
q = 0.6 × {10 − (− 80)} = 54 Kcal / kg
Gas specific heat: 0.6Kcal / kg ℃
The amount of liquefied natural gas LNG necessary for cooling the natural gas NG is determined as follows.
[0024]
When the liquefied natural gas latent heat is 120 Kcal / kg, the gas specific heat is 0.7 Kcal / kg ° C. (low temperature range), and the temperature difference between the liquefied natural gas temperature (−160 ° C.) and the cooling temperature (−80 ° C.) is 80 ° C.,
W ₁ × 54 = W ₂ (120 + 0.7 × 80)
However, W ₁ is the amount of returned natural gas NG W _{2 is the} amount of liquefied natural gas LNG for cooling, and the amount (W ₂ ) of liquefied natural gas LNG for cooling the returned natural gas NG is natural For the amount of gas (W ₁ )
W ₂ / W ₁ ≒ 0.3
That is, if the amount of liquefied natural gas LNG is about 30% with respect to the amount of natural gas returned to the LNG tank 1 through the vaporized gas return pipe 17 through the vaporized gas return pipe 17, Can be liquefied selectively. Therefore, the amount of liquefied natural gas is set to about 30% with respect to the amount of natural gas.
[0025]
In the case where the liquefied natural gas pipe having the cooling operation valve is connected to the liquefied natural gas pipe 23 connected to the vaporized gas return pipe 17, and the liquefied natural gas is allowed to flow, the natural gas is cooled. The amount of liquefied natural gas necessary for the liquefied natural gas is made to flow more than the predetermined amount calculated in the above calculation, and the liquefied natural gas pipe 23 is connected to the LNG tank 1 and joined with the liquefied natural gas pipe that is always flowing liquefied natural gas. In such a case, when the amount of liquefied natural gas is insufficient, a liquefied natural gas pipe having a cooling operation valve is connected to replenish the liquefied natural gas.
[0026]
Next, FIG. 2 shows another embodiment of the present invention, in which a vaporized gas return pipe 17 is inserted through the roof of the LNG tank 1 to near the bottom, and natural gas NG is put into a liquid layer in the LNG tank 1. It was designed to blow directly into the inside.
[0027]
In the case of the embodiment shown in FIG. 2, the natural gas NG returned to the LNG tank 1 is mixed with the liquefied natural gas LNG in the LNG tank 1 by being directly blown into the liquid layer in the LNG tank 1 and cooled. Therefore, the heavy components in the natural gas cooled and liquefied are dissolved in the liquefied natural gas LNG as they are, and the natural gas from which the heavy components are liquefied and removed is evaporated in the LNG tank 1. Since the gas has the same main component as the gas BOG, it is possible to prevent mist from being generated in the evaporated gas even when mixed with the evaporated gas.
[0028]
FIG. 3 shows still another embodiment of the present invention. In order to make the mixing of the natural gas NG and the liquefied natural gas LNG in the liquid layer of the LNG tank 1 more efficient, A vaporized gas return pipe 17 is inserted into a cylinder 24 installed so that the upper end protrudes above the liquid level, and the returned natural gas NG is blown into the liquefied natural gas LNG in the cylinder 24. .
[0029]
In the case of the embodiment of FIG. 3, the natural gas NG returned to the LNG tank 1 is directly blown into the liquid layer in the LNG tank 1, but the liquefaction in the cylinder 24 is surrounded by the cylinder 24. Contact mixing with the natural gas LNG is performed, the natural gas NG is cooled and the heavy components are liquefied and dissolved in the liquefied natural gas LNG. On the other hand, the gas floats in the cylinder 24 and rises above the LNG tank 1. However, since no heavy components are contained, no mist is generated in the evaporating gas.
[0030]
【The invention's effect】
As described above, according to the method for returning the natural gas to the tank at the time of adjusting the calorific value of the present invention, the natural gas to be returned is mixed with a predetermined amount of liquefied natural gas to cool the natural gas. Only the heavy components are liquefied and dissolved in liquefied natural gas and then returned to the LNG tank, or natural gas is blown back directly into the liquid layer of the LNG tank and the natural gas is returned to the liquid layer. Since the heavy components are liquefied by cooling and dissolved in the liquid layer, only the heavy components in the natural gas are liquefied, dissolved in the liquefied natural gas, and mixed with the evaporated gas BOG in the LNG tank. Since natural gas can be made free of heavy components, mist generation in evaporative gas can be prevented, and only heavy components in natural gas can be liquefied. In natural gas return piping Natural when the gas is cooled, as compared with the case of liquefied natural gas total amount, it can be reduced liquefied natural gas amount.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing an embodiment of the present invention.
FIG. 2 is a schematic view of an LNG tank unit showing another embodiment of the present invention.
FIG. 3 is a schematic view of an LNG tank unit showing still another embodiment of the present invention.
FIG. 4 is a schematic diagram showing an example in which natural gas is temporarily returned to an LNG tank when adjusting the amount of heat of conventional natural gas.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 LNG tank 2 Vaporizer 9 Calorific value adjustment part 17 Vaporized gas return piping 22 Mixer 23 Liquefied natural gas piping 24 Cylinder LNG Liquefied natural gas NG Natural gas

Claims (3)

In the natural gas return method in which the liquefied natural gas discharged from the LNG tank is vaporized by a vaporizer, and the natural gas is temporarily returned to the LNG tank when the calorific value of the vaporized natural gas is adjusted, the natural gas is returned to the LNG tank. A vaporizer return pipe is provided with a mixer, a liquefied natural gas pipe is connected to the vaporizer return pipe upstream of the mixer, and a predetermined amount of liquefied natural gas is mixed and mixed with the returned natural gas. A method for returning a natural gas to a tank during calorie adjustment, characterized in that a heavy component in the natural gas is liquefied and dissolved in the liquefied natural gas and then returned to the LNG tank. The natural gas according to claim 1, wherein only about 30% of the liquefied natural gas is mixed with the natural gas amount returned to the LNG tank through the natural gas return pipe to liquefy only heavy components in the natural gas. Return method to the tank when adjusting the amount of heat of gas. In the natural gas return method in which the liquefied natural gas discharged from the LNG tank is vaporized by a vaporizer and the natural gas is temporarily returned to the LNG tank when adjusting the calorific value of the vaporized natural gas, the vaporized gas return pipe is connected to the LNG tank. The natural gas to be returned is cooled by blowing it directly into the liquid layer in the LNG tank, and the heavy components in the natural gas are liquefied and dissolved in the liquid layer. A method of returning the natural gas to the tank when adjusting the calorific value of natural gas.

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