KR100490689B1 - Method of using boil off from liquefied gas and apparatus for performing the method - Google Patents

Abstract

In a plant for the production of fuel gas from boil-off and from liquefied gas with the aid of a combined heat exchanger (9), a compressor (4) is placed upstream of the heat exchanger in the gas line carrying boil-off. Compressed boil-off and liquefied gas pass in heat exchange in a combined heat exchanger (9) which has separate flow banks (7, 8) for liquefied gas and boil-off, respectively. From the combined heat exchanger (9), the two volumes of gas pass in a mixture to a consumer through a pipeline (5).

Description

Method for using boil off from liquefied gas and apparatus for performing the method

The present invention relates to a method of combining a boil-off from a liquefied gas with a gas produced by evaporating a liquefied gas and using it as a fuel gas.

The invention also relates to an apparatus for carrying out the method, wherein the boil off and evaporated liquefied gas is delivered together to a consumer, the apparatus comprising a storage tank for liquefied gas and a boiler from the storage tank. A combined heat exchanger having an off-flow line for off, a pump with an outflow line for liquefied gas from the storage tank, and two separate flow banks in a common outer shell, One of the banks is connected to an outlet line for liquefied gas for evaporation of the liquefied gas and the other bank is connected to an outlet line for boil off, the flow banks are open to a common mixing chamber, the common mixing chamber Is connected to a flow line extending to the consuming device.

NO-PS 176 454 discloses a method of combining a boil off from a liquefied gas with a gas produced by evaporating the liquefied gas and using it as a fuel gas, wherein the boil off and evaporated gases are compressed together and compressed Previously the boil off and liquefied gases are each overheated and evaporated in each region within the combined heat exchanger and collected in a common mixing chamber.

The publication also discloses a device in which boil off and evaporated gases are collected together and compressed. The apparatus includes a combined heat exchanger having a storage tank for liquefied gas, respective outlet lines for liquefied gas and liquefied gas from the storage tank, and two separate flow banks in a common outer shell. . One of the flow banks is connected to an outlet line for liquefied gas, while the other flow pipe bank is connected to an outlet line for boil off. The flow banks are open to the common mixing chamber, which is connected to a flow line extending to the consuming device.

The advantages obtained by the known techniques described above are that the compressor does not need to be cryogenic because the method and apparatus are simple, do not require a commonly used separator and the suction temperature of the compressor is quite high. A disadvantage of this prior art is that the compressor must essentially cover the entire volume of gas, ie both natural boil off and evaporated gas.

It is an object of the present invention to provide the devices and methods mentioned at the outset with the advantages of the prior art from NO-PS 175 654 while further simplifying the device.

This is achieved according to the invention by the above-described method, in which the boil off is compressed and delivered for heat exchange with the liquefied gas, which is then mixed with the liquefied gas evaporated during the heat exchange process.

By the fact that the compression takes place before heat exchange and only the boil off is compressed, the advantage is obtained that only compression is applied to the volume of the boil off and no compression is applied to the entire volume of the gas. As a result, required power is reduced and capacity control is simple.

According to the invention, an apparatus as described above is proposed, wherein the apparatus is characterized in that a compressor is provided in the outlet line for off-voile prior to the combined heat exchanger.

By placing the compressor in a boil off outlet line upstream of the heat exchanger, the compressor only needs to bear the boil off volume and does not have to cover the entire volume of gas. In the case of LNG, the compressor must be configured to operate with gases as low as -140 ° C, but this disadvantage is that the compressor is smaller in size, the power required is reduced, the working area is smaller and the capacity control is more It is also rewarded by the advantage of simplicity. A further advantage is that the combined heat exchanger can be sized to withstand higher pressure drops, resulting in reduced shell size and lower manufacturing costs. The problem lies in the choice of compressor material, which may be undesirable, but as mentioned above, this disadvantage is eliminated by compact compressors.

The invention will be described in more detail with reference to the drawings schematically illustrating the foregoing apparatus.

In the figure, reference numeral 1 denotes a storage tank for liquefied gas, for example, an LNG tank of an LNG carrier. Due to the heat penetration from the surroundings, so-called boy off is produced. It accumulates in the dome 2 of the storage tank 1 and can be discharged through the outlet line 3 for boil off. The outlet line 3 leads to the compressor 4. In the compressor 4, the boil off is compressed and the temperature rises accordingly. From this compressor, compressed boil off proceeds to the combined heat exchanger 9.

The boil off is used as fuel gas in the propulsion engine of the ship. The device is liquefied natural gas is withdrawn by the pump 11 and combined via the outflow line 10 when the boil off is not sufficient, i.e. when a larger amount of fuel gas is required than the boil off that can be supplied. Led to a heat exchanger (9).

The combined heat exchanger 9 is equipped with separate flow banks 7 and 8 for each liquefied gas and boil off. The liquefied gas and the boil off are heat exchanged with an external hot flow, as indicated by the arrows in the figure. In most cases this flow, which is steam, is transferred from the cell side of the heat exchanger.

The two gas flows accumulate in the mixing chamber 6 and proceed through the flow line 5 to a consuming device, for example a burner, not shown.

Claims (2)

A method of combining a gas generated by evaporating a liquefied gas with a boil off from the liquefied gas and using it as a fuel gas, Compressing the boil off to heat exchange with the liquefied gas with an external hot medium flow and mixing the compressed boil off with the liquefied gas evaporated during the heat exchange process to form a fuel gas. How to use Boyle Off. A device in which boil off and evaporated liquefied gas are delivered together to a consuming device, A storage tank 1 for liquefied gas; Outflow line (3) for boil off from said storage tank (1); A pump (1) to which an outflow line (10) for liquefied gas from the storage tank (1) is attached; And A combined heat exchanger (9) having two separate flow banks (7, 8) in the common outer shell; The one flow bank 7 is connected to an outflow line 10 for liquefied gas and the other flow bank 8 is connected to a boil off outlet line 3, the flow banks flowing to the consuming device. Open to a common mixing chamber 6 connected to line 5, the combined heat exchanger 9 provides a hot flow medium supply for delivering a hot flow medium on the shell side of the heat exchanger 9. An apparatus for carrying out the method according to claim 1, comprising a flow connection with Apparatus using a boil off from liquefied gas, characterized in that a compressor (4) is provided in the boil off outlet line (3) prior to the combined heat exchanger (9).