DE2165388C2 - Hold method and device for emptying Flussiggasspeicherbe - Google Patents

Description

A minimization of the amount of gas required for emptying is achieved in that after a further feature of the method, the number of the different emptying periods assigned Container is set so that the first part of the container of the first emptying period such ■ Is able to absorb the amount of gas under excess pressure that of the last part of the container Discharge period under excess pressure contained gas plus corresponds to the amount of gas contained in the remaining containers under storage pressure. A Such a step makes it possible that for emptying all the container only the emptying of the first part of the container of the first evacuation period required amount of gas is required so that the amount of game remaining in the containers during the return transport of the ship to them reduce the first portion.

A constant time sequence of the emptying process, which is essential for technical reasons is guaranteed by the same delivery rates per unit of time in all emptying periods. There however, the container numbers assigned to the various emptying periods are not the same (in the As a rule, the number of containers assigned to a first emptying period is greatest), the constructive one lies Consequence for performing this process step in different sized cross-sections of the liquid gas delivery lines of containers which are assigned to different emptying periods, wherein as the number of containers decreases per emptying period, the cross-sections of the liquid gas delivery lines these containers are to be enlarged.

A schematic embodiment of an apparatus for performing the method is shown in FIG Drawing shown.

In this exemplary embodiment, a liquid methane tanker consisting of a large number of storage containers is to be emptied in four emptying periods. The different emptying periods are represented by A, B, C and D. A number of storage containers are assigned to each emptying period, which in the exemplary embodiment are each combined into containers 1, 2, 3 and 4 for the sake of simplicity. The volumes of the containers 1, 2, 3 and 4 are different, which will be explained in more detail using a numerical example below.

During the emptying, the container 1 is first emptied in a first emptying period A. Here, gaseous saliva is sucked in by a compressor 5 via lines 6 and 7 from an expansion tank 8, compressed and pushed into the tank 1 via line 9 'and gas supply line 9 of the tank 1. The valves 10, 11, 12, 13 and 14 are open, while all other valves 15 to 26 are closed. As a result of the overpressure now present in the container 1, liquid gas is pressed into the expansion container 8 both via the instrument line 27 and the line 28 and via the delivery line 29 and the line 30. The "pressure controller" 43a is connected to the line 28 and gives the impulse to close the valves 13 and 14, which are coupled to one another, as soon as the liquid level in the container 1 falls below the level. In this case, gas enters the lines 27 and 28, so that the pressure in front of the valve 14, which has only a small passage, rises and both valves 14 and 13 after reaching a certain value registered by the pressure controller closes.

A small one indicated by the level α

The amount of liquid is returned in all containers.

relaxed in order to keep them cold during the ship's return voyage.

After the container 1 has been emptied, which is registered by closing the valves 13 and 14 now manually or automatically the valves 11

ίο and 12 closed and valves 15, 17, 21 and 22 open. In a second emptying period B , gas under excess pressure is now sucked in by the compressor 5 from the container 1 via the lines 9 and 31, compressed and via the lines 9 ', 32'

and the gas supply line 32 is supplied to the container 2. Liquid methane now flows from this container via lines 33 and 28 and lines 34 and 30 in the expansion tank 8 until the level in the tank 2 is reached. Be now

ao the valves 21 and 22 through the "pressure controller" 43Λ and valve 17 closed while the Open valves 16. 19, 23 and 24.

In the third emptying period C "which is now beginning, the compressor 5 is still under

Gas from the container 1 remaining at a slight overpressure as well as gas from the container 2 under normal overpressure are sucked in via the lines 31, 9 and 32, compressed and fed to the third container 3 via the lines 9 ', 32', 35 'and the gas supply line 35 so that this is also emptied via lines 36 and 28 and lines 37 and 30 down to level α. After the valves 23 and 24 have been closed by the pressure controller 43r and valve 19 and after the valves 18, 20, 26 and 25 have opened, the fourth emptying period D is now initiated.

Gas is sucked in from the compressor 5 via the lines 31, 35, 32 and possibly also the line 9, compressed and via the lines 9 ', 32'.

35 ', 38' and the gas supply line 38 are supplied to the fourth container 4. Liquid methane escapes the lines 39 and 28 as well as the lines 40 and 30 in the expansion tank 8 to also in the tank 4 the »pressure controller« 43i / reaching the

Levels α registered and the valves 26 and 25 closes.

The suction pressure of the compressor 5 is controlled by a regulator (not shown) during all emptying periods on the storage pressure of the liquid

Methane, which is usually 1 ata, i.e. around atmospheric pressure, is kept.

After the emptying process has ended thus only the container 4 is under overpressure, while all the other containers are under storage pressure condition.

Finally, it should be noted that liquid methane is pumped ashore via line 42 while Gaseous methane can be released on land via line 7 or obtained from there. Necessary for this Pumps are not shown in this embodiment.

A safety valve 41 protects the expansion tank 8 from excess pressure.

Using a numerical example, the method outlined above, especially with regard to the Distribution of the container volumes over the individual emptying periods are explained again in more detail.

The total storage volume of the four containers 1, 2, 3 and 4 is 10 ⁵ m ³ . The storage pressure of the liquid methane is 1 ata, the storage temperature 112 ° K. An overpressure of 2 atü is used for emptying. 5 ·

First, the volume of the gas amount is to be calculated under normal conditions, it takes to empty all the containers, wherein it is assumed that the last Enlleerungsperiode 12.3 ° / ₀ of the total container volume, ie 12300 m ³ includes.

After emptying, there is an amount of gas below 1 ata and 112``K in all containers. This gives 10 ⁵ · ^ - = 2.44 · 10 ⁵ Nm ³ . To this is added the volume of an additional amount of gas which is located in the container 4 assigned to the last emptying period under a pressure increased by 2 ata. This additional volume is calculated as - ¹ V. 2.44 x 10 ⁶ x 2 ata = 6 x 10 * Nm ³ . Thus * °

1UU

the volume of the total amount of gas required for evacuation is 3.04 · 10 ⁵ Nm ³ .

In contrast, emptying according to the prior art would require a gas volume of 7.32 · 10 ⁵ Nm ³ .

The following container volumes are now emptied in the individual emptying periods:

1st emptying period:

3.04 · 10 ⁶ ■

1.12
273

= 4.15 -10 ⁴ m ³ tank capacity.

2nd emptying period:

Two thirds of that, because of the amount of gas in the container below 3 ata only the part corresponding to a pressure of 2 ata is available for the second evacuation period. In the second emptying period, 2.77 · 10 * rn ^{3 of} liquid methane are pumped.

3rd emptying period:

Two thirds of the methane produced in the second emptying period = 1.85 · 10 * m ³ .

4th emptying period:

Two thirds of the third emptying period = 1.23-1O ⁴ ItI ⁸ .

The sum of the amount of liquid gas delivered in all four emptying periods is thus m ⁸ .

In order that the most uniform amount of methane possible can be promoted per unit of time, the Containers associated with later emptying periods can be emptied more quickly. This is done through an enlargement the cross-sections of the methane conveyor pipes reached this container.

The process can also be carried out with inert gas, ζ. Β Nitrogen.

1 sheet of drawings

Claims (7)

... compressed gaseous storage medium or claims: inert gas in the container and a device for 1. Procedure for emptying a variety of performing the procedure! .. It is known to empty liquid gas containers by introducing compressed 5 storage containers within all containers an overgaseous storage medium or inert gas in the pressure, for example by introducing compressed containers, thereby ge ke η η ze I η et that mated gaseous storage medium to generate, in a first emptying period a first in order to thereby discharge liquid gas out of the containers-part of the container that press shut in a second. The size of the excess pressure to be generated, the emptying period of the now gaseous content io depends on the specific weight of the liquid gas to be extracted, compressed to be conveyed by the first part of the container, the height of the liquid and a second part of the container to its gas container and the required Inlet pressure of the emptying is supplied and that these pumps, which promote the liquid gas on land. In the driving style, possibly in further emptying rule, the overpressure to be generated is a few atmospheres. period is repeated until all 15 At the end of the emptying process, all containers are emptied and only the last part of the container under the container of the last emptying period required for liquid gas pumping is under overpressure.
Overpressure. Especially when emptying large ones from one 2. The method according to claim 1, characterized by a multitude of storage containers existing liquid draws, This known method proves that the first part of the container of the first 20 gas tankers Emptying period includes so many containers that, however, is disadvantageous because the desired short one because of the dci the amount of gas contained in these under excess pressure, the times the ships lay berthed after emptying in the overpressure prevailing in the last part of the containers of the last of all containers is not the same Emptying period contained under excess pressure can be discharged on land quickly enough so that Amount of gas plus that in the remaining containers 25 the still relatively high gas content of the container during amount of gas contained under storage pressure. the return journey of the ship must be consumed. 3. The method according to claims 1 and 2, but this means a considerable loss characterized in that in each emptying usable cargo. period the same amount of liquid gas per unit of time. B. in one of a variety of is promoted. 30 existing methane tankers for liquefied gas tanks, the 4. Device / in order to carry out the method under an overpressure of 2 atü was emptied, per according to one of claims 1 to 3, characterized in cubic meters of cargo space 7.3 Nm ³ gaseous methane, indicates that each container (1, 2, 3 , 4) Gas- Since 1 m ^{3 of} liquid methane ^{results in 586 Nm 3 of} gaseous supply (9, 32, 35, 38), liquid gas delivery (29, 34, methane, this means a loss of useful 37, 40) and instrument lines (27, 33, 36, 39) 35 free cargo space of about 1.25%. has, the entirety of those containers The invention is based on the object of this ter, which are assigned to an emptying period, to reduce the costly loss of cargo space of a liquid gas tanker with their gas supply lines both at the inlet, without the timing of the aisle as well as the Output of at least one emptying compared to the state of the art to be displaced automatically controllable compressor (5) 40,
are closed. The object is achieved in that in a 5. Apparatus according to claim 4, characterized in that the first emptying period is a first part of the container indicates that the gas supply lines (9, 32, is emptied that in a second emptying period 35, 38) of all containers (1, 2, 3, 4) to the outlet of the now gaseous content of the first part of the of the compressor (5) and exclusively that of a 45 container r.bgesaugt, compressed and a second last emptying period (D) assigned to part of the container is fed to their emptying the input of the compressor (5) automatically and that this procedure can optionally be further controlled are connected. ren emptying periods is repeated until 6. Apparatus according to claim 4, characterized in that all containers are emptied and only the last part indicates that the liquid gas delivery (29, 34, 37, so the container of the last emptying period under 40) and instrument lines (27, 33, 36, 39) the overpressure is present. Container (1. 2, 3, 4) each emptying period with This process sequence of emptying a multiple an expansion tank (8) automatically tax number of liquefied gas storage tanks enables it in are connected and that the vapor space of the advantageous way, the overpressure in already emptied Relaxation tank (8) with the entrance of the 55th container already during the emptying of further Compressor (5) is controllably connected. Reduce container to storage pressure, so that 7. Apparatus for performing the method, finally, only the last part of the container, the according to claim 3, characterized in that it is assigned to a last emptying period, unler Cross-sections of the liquefied gas delivery lines remain in an overpressure. Thus, there is a decrease only a few containers comprehensive emptying 60 reached the amount of gas remaining in the cargo hold period are greater than that of emptying periods, and the utilization of the usable cargo space of the to which larger numbers of containers are assigned. Liquefied gas tanker improved. Another advantage of the method is that to empty all storage tanks a lower one 65 amount of gas is required, as in previous developments The invention relates to a method for emptying emptying periods required gas quantities successively for a large number of further emptying periods under storage pressure can be used Liquefied gas storage containers by introducing NEN.