DE2411611C3 - Method of transporting natural gas through a pipeline - Google Patents

Description

The invention relates to a method for transporting natural gas through a pipeline.

A method for transporting natural gas through a pipeline is known, which consists in that one Natural gas is pumped away through the pipeline with the help of compressor stations which run along the pipeline are set up at specified distances from each other. The transport of natural gas takes place at a Temperature that almost corresponds to the temperature of the surrounding medium

The main disadvantage of the known method is the relatively low throughput of the pipeline, which leads to a large specific investment for the transport of the gas.

Also known is a method of transporting natural gas through a pipeline in which the gas is compressed to a pressure of 100 to 120 kp / cm ² and cooled to a temperature of about -70 ⁰ C (see, for. Example, the pamphlet by the authors SF G udk ο w, OA Benjaminowitsch, GE Odischarija "On the rational areas of application of various working schemes for the transport of large amounts of natural gas", lecture at the 11th International Gas Congress, Moscow Publishing House, 1970).

Also known is a method for transporting natural gas, which consists in liquefying the natural gas and then pumping it ^{through the pipeline in the supercooled state at a pressure of about 50 kp / cm 2} and a temperature of about -12O ^{0 C.} The forwarding of the liquefied gas is accomplished by pumping stations that are set up along the pipeline at predetermined distances from one another.

The increase in the throughput of the pipeline is achieved in the above-mentioned method λ W-

d Τ "'

where means

- ^ pressure gradient per unit length of the pipeline;

λ coefficient of resistance;

d diameter of the pipeline;

W speed of movement of the current in the

Pipeline;
ρ Density of the natural gas to be pumped.

From this equation it follows that an increase in the density ρ by η times under the condition that the quantity -ψ- remains constant requires a decrease in the speed W \ im n " ² times.

Therefore, increasing the density ρ by n times only increases the throughput of the pipeline by n ^{l / 2} times.

It can be seen from the above that the increase in the density of the gas to be pumped does not result in any leads to a proportional increase in the throughput of the pipeline. At the same time, the increase requires the gas density an increase in the investment costs associated with the use of thick-walled Pipes in the event of a pressure increase or pipes made of expensive cold-resistant materials in the event of a temperature decrease connected is

A considerable increase in the throughput of the pipeline cannot be achieved by increasing the speed W of the flow, because in this case the pressure losses per unit length of the pipeline increase proportionally to the square of the flow velocity.

The purpose of the present invention is to eliminate the aforementioned drawbacks.

The invention is based on the object of creating such a method for transporting natural gas, which with a high density of natural gas and a relatively low specific investment outlay, a considerable one Allowed to ensure an increase in the throughput of the pipeline.

This object is achieved in that the method for transporting natural gas through the Pipeline the natural gas is conveyed according to the invention in the form of hydrates, which are introduced into containers are, the latter are inevitably moved by the pipeline filled with natural gas, in the a Pressure and a temperature are maintained which allow the state of aggregation of the hydrates to be kept during transport.

The inevitable movement of the container through the pipeline is expediently carried out by means of natural gas, which is previously compressed and cooled, the gas pressure being in the range from 50 to 20 kp / cm ² and the temperature correspondingly in the range from -40 to -10 over the length of the pipeline ⁰ C change.

The utilization of the natural gas for the forced movement of the containers through the pipeline allows to further increase the amount of natural gas transported through the pipeline.

It is advisable to make the containers open, to partially load them and to connect them to a train, arranging the trains at such intervals as they move along the length of the pipeline are that the greater part of the inevitable moving natural gas is within the Container is located

The combination of the containers in a train and their partial filling with hydrate offers the possibility of the size of the pressure vessel by pressure equalization by means of a gas inflow from the containers into the pipeline at the end of the movement.

The method for transporting natural gas through the pipeline according to the invention allows the The throughput of the pipeline is at least 3 to 4 times greater than that of a pipeline enlarge, in which the natural gas is pumped through at a temperature that the temperature of the surrounding Medium is close to The specific investment cost when carrying out the method for Transport of natural gas according to the invention is considerable over the methods given above reduced, as thin-walled carbon steel pipes are used in such a transport of natural gas can be.

In the following an embodiment of the invention with reference to the drawings described, it shows

F i g. 1 the block diagram of the system for transporting natural gas;

2 shows the curve of the phase equilibrium of Hydrate;

F i g. 3 shows the arrangement of a train consisting of containers in the pipeline in longitudinal section;

4 shows the diagram of the pressure change of the Movement of the container causing natural gas along the length of the pipeline.

A plant 1 (FIG. 1) for the production of hydrates is supplied with natural gas and water under the same pressure ^{under a pressure of 60 to 40 kp / cm 2.} The gas is cooled to a temperature of -20 ...- 30 ⁰ C and divided into two gas streams. One stream is mixed with the atomized water, which has previously been cooled ^{to a temperature of +1 ... +2 0 C.} As a result of the mixing of natural gas with the atomized water, finely dispersed hydrates are formed. Furthermore, these hydrates are subcooled with another stream of natural gas, which is pre-cooled to a temperature of around -45 ° C. The supercooled hydrates are then fed to the loading devices 2, in which the loading of the containers (not shown) takes place. The natural gas hydrates can be produced by any other suitable method.

Under normal conditions, ie at atmospheric pressure and temperature + 20 ° C, the density of the natural gas is approximately 0.72 kg / m ³ . One ton of hydrate contains about 129 kg of natural gas. It can be seen from this that the density of the natural gas in the hydrate is approximately 130 kg / m ³ , and assuming that the hydrates in the container are in the granular state, the natural gas density in the hydrates in the container is 103 kg / cm ³ . Such a density of the natural gas in the hydrates corresponds to the density of the natural gas which is below the; Pressure of 130 kp / cm ² . To maintain the state of aggregation of Erdgashydraten at the temperature of -20 ⁰ C (F i g. 2), a pressure of about 10 kp / cm ² is required (the point "a" of the curve of the phase equilibrium of hydrates for pure methane CH4).

The containers loaded with hydrate are inevitably transported through the pipeline 3, which is filled with natural gas (Fig. 1) moved For forced movement! Natural gas is used, which has previously been compressed and converted into Stations 4 is cooled at predetermined distances from each other over the entire length of the Pipeline 3 are set up. The stations mentioned contain compressor and cooling systems (not shown).

In the stations 4, the natural gas, which brings about the inevitable movement of the container is compressed to the pressure of 50 kgf / cm ² and at the temperature of -40 ⁰ C cooled During the movement of the container through the pipe 3 with the speed up to 120 km / h, the pressure drops in it gradually and is in front of the next following station 4 about 20 kp / cm ^2, while the temperature at -1O ⁰ C (point "ix <in Fig.2) increases in these thermodynamic parameters of the natural gas , which causes the inevitable movement of the container, the natural gas hydrates in these retain their physical state.

At the end points of the pipeline 3, the containers are fed to a system 5 for the destruction of the hydrates, where the decomposition of the hydrates into gas and water takes place by increasing the temperature above the equilibrium temperature (point »<x <in Fig. 2) from the system 5 to the consumer (not shown) and the water is diverted into industrial water pipes (not shown) The empty containers enter the pipe 6 and return via this to the loading device 2, this being done by means of 5 of the natural gas under a pressure of 1, 2 to 3 kp / cm ² happens at the temperature of the surrounding medium at a speed of up to 250 km / h

In order to increase the throughput, the containers 7. 8. 9 (Fig. 3) are used to form a train connected with each other. When transporting natural gas hydrates in trains consisting of the containers the container partially loaded, the free volume of each container 7, 8, 9 being filled with natural gas, which the inevitable movement of the containers 7, 8, 9 through the pipeline ensures To connect the Inside the pipeline 3 with the free volume of the container 7, the latter is completely open run on one side.

The container 8 has hatches to connect its free volume to the interior of the pipeline 10 and the container 9 column 11.

The trains can be put together from the containers in any combination.
The free volume of the containers 7, 8, 9 is filled with

_5S Natural gas, which is in the pipe 3 and causes the train to move inevitably, and moves together with the container. During the movement of the containers 7, 8, 9, the natural gas filling their free volume serves as a source of potential energy. Depending on the pressure drop in the longitudinal direction of the pipeline 3, the natural gas in the container enters the latter and reduces the size of the pressure drop. The curve "d" (Fig. 4) shows the character of the drop in pressure P of the natural gas over the length 1 and pipe 3 on the pipe section between two adjacent stations 4 or between the loading device 2 and the station 4 or between the station 4 and of Annex 5 to the destruction

24 1 1 oil 1

of hydrates in the movement of trains in which the containers 7, 8, 9 are partially loaded with natural gas hydrates are. The curve "e" indicates the pressure drop in the case of containers fully loaded with natural gas hydrates.

The trains are moved along the length of the pipe 3 at such intervals during their movement arranged that the greater part of the natural gas, which causes the movement of the trains, is in the free volume said container is located

The method of transporting natural gas is ι ο carried out as follows.

The hydrates produced in the plant 1 for the formation of hydrates reach the loading device 2, where they are introduced into the containers which are fed to the pipeline 3. Together with the loaded containers is of the pipeline 3, a compressed to a pressure of 40 to 60 kp / cm ² and abgekehltes to a temperature of about -40 ⁰ C natural gas supplied to the transport of the container through the pipe 3 is due to the energy of the compressed and cooled natural gas. During the movement of the container over the length of the pipeline 3, the pressure of the natural gas moving the container decreases as a result of gas-dynamic and mechanical losses during the conveying process surrounding medium as well as mechanical friction of the container on the walls of the pipeline 3.

The pressure and temperature of the natural gas moving the container should be over 20 kp / cm ² and below -10 ° C in each case over the entire transport section in order to maintain the physical state of the natural gas hydrates transported in the containers. In stations 4, in which E containers with the hydrates and natural gas arrive, the pressure and temperature of the latter increase and decrease around the container to be able to convey to the next station 4. After the stations 4 get the container and this moving natural gas into the plant 5 to destroy the hydrates, where by an increase in temperature Hydrates above the equilibrium temperature of hydrate formation these are broken down into water and gas. The gas is fed to the consumer and the water to industrial water pipes.

The use of the natural gas to forcibly move the containers through the pipeline is permitted it is to further increase the amount of natural gas transported in the pipeline.

The empty containers pass from the system 5 into the pipeline 6, in which they are returned to the loading device 2. The pressure in the pipe 6 is maintained in a range of 3 ... 1.2 kp / cm ² , while the temperature is the same as that of the surrounding medium

When transporting natural gas according to the method according to the invention through a pipeline with the Diameter J420 mm, their output is about 150 billion cubic meters of gas per year, with the Pipeline consists of only one strand

When transporting natural gas according to the known method in pipes with a 1420 mm diameter at a pressure of 75 kp / cm ² and a temperature that corresponds to the temperature of the surrounding medium, their throughput is about 30 billion cubic meters of gas per year.

Spiral seam pipes made of conventional carbon steel can be used to transport natural gas Printing are considerably cheaper. Another beneficial effeki of the process according to the invention, the simultaneous transport of large quantities is also technical pure water for use in industry

For this purpose 2 sheets of drawings

¥ 556

Claims (3)

Patent claims: 1. A method for transporting natural gas through a pipeline, characterized in that that the natural gas is transported in the form of hydrates, which are placed in containers, the latter being inevitably moved by a pipeline (3) filled with natural gas, in the a pressure and a temperature are maintained which allow the physical state to maintain hydrates during transport. 2. The method according to claim 1, characterized in that the positive movement of the container through the pipeline takes place by means of natural gas which is previously compressed and cooled, the gas pressure over the length of the pipeline (3) in the range of 50 to 20 kp / cm ² and the temperature changes accordingly in the range of -40 to -10 ° C 3. The method according to claim 1 and 2, characterized characterized in that the containers (7, 8, 9) run open, partially loaded with hydrates and then to be connected to trains, the trains during their movement over the length of the Pipeline (3) are arranged at such intervals that most of the inevitable Moving the trains causing natural gas is located within said container 3 ° achieved by increasing the density of the natural gas to be pumped The movement of the current through the pipeline is described by the following equation: