RU2523923C1 - Oil transportation in pipeline by reverse transfer - Google Patents

Abstract

FIELD: oil-and-gas industry.

SUBSTANCE: process is intended for oil transfer, including highly paraffinic oil, ay low temperatures and can be used for prevention of oil freezing in large-diameter oil line at low rate transfer. Method comprises consecutive transfer of oil, first, in forward direction and, then, in reverse direction at oil heating at oil transfer stations. Oil in transferred in forward direction in volume (V₀+V) and in reverse direction in volume V, where V₀ is oil volume to be transferred in forward direction, V is reverse oil volume required for oil line section heating and making 1/2 to 2/3 pipeline section volume.

EFFECT: higher efficiency of oil efficiency at low-rate transfer.

6 cl, 1 dwg

Description

The invention relates to the oil industry, and in particular to methods of transporting oil, including highly paraffin, at low temperatures, and can be used to prevent freezing of oil in a large diameter oil pipeline when pumping it with low productivity (until the oil pipeline reaches its design capacity).

When designing a “hot” oil pipeline, it is necessary to ensure its uninterrupted operation in a different range of pumping capacities (from minimum to maximum) by stages (years) of development. The diameter of the pipeline is determined from the condition of ensuring maximum productivity and capabilities of pumping equipment at oil pumping stations. With minimal productivity, at the initial stages of the development of the pipeline, the oil flow rate is low, which determines an intensive temperature drop along the length of the pipeline up to ambient temperature.

When pumping oils with a pour point above ambient temperature, it is necessary to ensure a thermal pumping regime, in which the temperature of the oil in the pipeline should not fall below the pour point even after the pipeline is stopped (during the scheduled shutdown time). Therefore, for safe operation of the pipeline, for example, in the conditions of the Far North or with overhead installation of the pipeline, it is necessary to apply pumping technologies that exclude oil freezing in the pipeline.

To solve this problem, usually set the waypoints for heating the pipeline. However, at low pumping capacities it is necessary to establish a large number of such points (every 5-10 kilometers), which is not economically feasible in the conditions of temporary operation of the oil pipeline with low productivity, until reaching the maximum design operating mode.

In addition, it is also possible to use systems of track electrical heating of the pipeline (see, for example, Chinese patent CN 2280205). However, this technology is also not economically viable in conditions of a significant length of the pipeline.

The closest analogue of the claimed invention in terms of features is a method for shuttle heating of the pipeline between two oil pumping stations equipped with heating points (see A.A. Korshak et al. Design and operation of gas and oil pipelines. - St. Petersburg: Nedra, 2008, p.355 -358). According to the method, the heating fluid (in particular oil) is pumped first in the forward and then in the opposite direction. This method can be used to heat the section of the pipeline during its preliminary adjustment before starting, however, it is not suitable for transporting oil.

The task of the claimed invention is to provide a method for transporting oil at low pumping rates.

The technical result of the claimed invention is to provide the required temperature regime of oil transportation while increasing the efficiency of transportation in low productivity conditions.

The specified technical result is achieved due to the fact that the method of transporting oil in the pipeline between the oil pumping stations involves sequential pumping of oil first in the forward and then in the opposite direction when heating oil at the oil pumping stations, while in the forward direction the oil is pumped in volume (V ₀ + V), and in the opposite direction - in volume V where V ₀ - the volume of oil that must be transported in the forward direction, V - the volume of the return oil required for warming nave portion and eprovoda of from 1/2 to 2/3 portion of the conduit volume.

In addition, the specified technical result is achieved due to the fact that

- the transported volume V ₀ and the return volume V of oil is placed in the tank farms of the respective oil pumping stations;

- the temperature of oil heating at oil pumping stations is from 30 ° C to 55 ° C;

- the productivity of pumping oil in the forward and reverse directions is selected from the conditions for maintaining the required temperature of the pumped oil, taking into account heat exchange with the environment;

- in the forward and reverse direction, oil is pumped with the same capacity, while the pumping time in the forward direction is longer than in the opposite direction;

- the time for pumping oil in the forward and reverse directions is the same, while the productivity of pumping in the forward direction is greater than in the opposite direction.

The claimed method of reverse (shuttle) oil pumping, based on alternately changing the direction of pumping, allows on the one hand to provide the required temperature of the oil in the pipeline at low pumping rates, and on the other hand to reduce the cost of heating the oil, as well as reduce the required volume of tank farms needed to create volumes for oil displacement in the forward and reverse directions.

At the same time, the inventors found that reverse pumping of oil with a volume of less than 1/2 of the volume of the pipeline section will not provide the required temperature of the pumped oil, and when pumping the volume of more than 3/4 of the volume of the pipeline section, the cost of oil transportation will increase dramatically pumping volumes and tank farm volumes for oil distribution.

The essence of the claimed method is illustrated in figure 1.

Oil is transported between two oil pumping stations (NPS) 1 and 2, equipped, respectively, with oil heating points 3 and 4 and tank farms 5 and 6.

The transported oil is heated in the heating points 3 and 4, respectively, located at the pump stations 1 and 2. The temperature of the oil heating, depending on the transportation conditions, is determined by thermohydraulic calculation and can range from 30 ° C to 55 ° C.

At the first stage (Fig. 1, a), oil is pumped in the forward direction (from NPS 1 to NPS 2) in a volume consisting of the volume V ₀ , which must be transported to NPS 2, and the return volume V for heating the pipeline (the volume of pumped oil in the forward direction = V + V ₀ ). Volume V is from 1/2 to 2/3 of the volume of the pipeline in the area between the NPS. The transported volume of oil V _{0 is} placed in the tank farm 6 of the NPS 2 from where it can be pumped to the next along the NPS.

In the second stage (figure 1, b) the return volume V of oil is pumped back to the OPS 1, thereby ensuring the heating of the pipeline. In this case, the return volume V is placed in the tank farm 5 of the NPS 1 for the next cycle.

This process is repeated cyclically, thereby ensuring the transportation of oil from PS 1 to PS 2 in a volume of V ₀ for each cycle, when the pipeline is heated.

The productivity of pumping oil in the forward and reverse directions is selected from the conditions for maintaining the required temperature of the pumped oil, taking into account heat transfer with the environment.

At the same time, two options of pumping modes are used to move the required volume of oil:

1) In the forward and reverse directions, oil is pumped with the same capacity, while the pumping time in the forward direction is set longer than in the opposite direction.

2) The time for pumping oil in the forward and reverse direction is chosen the same, while the productivity of pumping in the forward direction is set more than in the opposite direction.

Thus, the application of the claimed method of oil transportation at the initial stages of the development of the pipeline avoids the additional cost of heating oil by traditional methods, which significantly reduces the cost of building and operating a “hot” pipeline.

Claims (6)

1. A method of transporting oil in a section of a pipeline between oil pumping stations, comprising sequential pumping of oil first in the forward and then backward directions when heating oil at the oil pumping stations, while in the forward direction the oil is pumped in volume (V ₀ + V), and opposite direction - in volume V where V ₀ - the volume of oil that must be transported in the forward direction, V - the volume of the return oil required for heating the pipeline section and which constitutes from 1/2 to 2/3 of the volume portion Pipelines water. 2. The method according to claim 1, in which the transported volume V ₀ and the return volume V of oil is placed in the tank farms of the respective oil pumping stations. 3. The method according to claim 1, in which the oil at oil pumping stations is heated to a temperature of from 30 ° C to 55 ° C. 4. The method according to claim 1, in which in the forward and reverse direction, the oil is pumped with a capacity selected from the conditions for maintaining the required temperature of the pumped oil, taking into account heat exchange with the environment. 5. The method according to claim 1, in which the forward and reverse oil is pumped with the same capacity, while the pumping time in the forward direction is longer than in the opposite. 6. The method according to claim 1, in which in the forward and reverse direction, oil is pumped for the same time with a pumping capacity in the forward direction greater than in the opposite.