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European Journal of Applied Sciences – Vol. 9, No. 6

Publication Date: December 25, 2021

DOI:10.14738/aivp.96.11430. Kosisochukwu, N. C., & Saturday, E. G. (2021). Analysis of Crude Oil Production Using Gas Lift. European Journal of Applied Sciences,

9(6). 598-608.

Services for Science and Education – United Kingdom

Analysis of Crude Oil Production Using Gas Lift

Nwudoh Chisom Kosisochukwu

Offshore Technology Institute, University of Port Harcourt

Ebigenibo Genuine Saturday

Department of Mechanical Engineering, University of Port Harcourt

ABSTRACT

Gas lift is used to increase production by reduction in the density of the oil column

in the tubing, reduction of the flowing bottom-hole pressure which is affected by the

hydrostatic pressure of the fluid column and by providing external energy to the oil.

In this study an oil field in the Niger Delta was used as case study; it has a production

life span of over ten years with characteristics such as high gas-oil ratio (GOR) and

high reservoir pressure which makes gas lift suitable for optimizing the wells. The

aim of this study is to select the gas lift method suitable for optimum production in

the wells using the production modelling softwares PROSPER, and GAP. Simulation

studies were conducted using data from two wells in the oil field. The performance

of continuous and intermittent gas lifted performance on two wells were compared.

The results indicated that continuous gas lift system will be suitable for a well that

has high flow rate and high GOR. Also, intermittent gas lift system will be suitable

for a well that has lower reservoir pressure and low productivity. Sensitivity

analysis of water cuts, gas injection rates and well head pressures were carried out

to investigate how the wells will respond to changing operating conditions such as

increasing water cut, increasing gas injection rates and increasing well head

pressures in the future.

Keywords: Gas lift, Gas-Oil Ratio, Continuous and Intermittent Gas Lift System, Sensitivity

Analysis.

INTRODUCTION

Production of crude oil from the well can be achieved with the natural energy of the well at its

early life, when the natural drive is most active and crude oil is produced from the reservoir at

commercially viable rate. Factors most responsible for this are the gas cap, solution gas, and

water drive. A well produces with a combination of these drives at a particular time;

subsequently as production progresses, the reservoir natural energy depletes leading to

reduced reservoir pressure and bottom hole flowing pressure (BHFP) that accompanies the oil

to the surface, increased water cut with resulting decrease in gas-liquid ratio (GLR). Increased

pressure drop and water cut are often experienced in mature fields that has been in production

over a period of time. Other challenges that could also affect decline in production rate are

inappropriate perforation method, inadequate design of the well production system and inept

management of a well. At this point where the well is unable to produce at its own natural

energy and at economical production rate, a best known option is the application of artificial

lift method for enhanced oil recovery (EOR). Artificial lift systems are designed to assist

reservoirs that may not be able to produce its formation fluids using its own natural drive at

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European Journal of Applied Sciences (EJAS) Vol. 9, Issue 6, December-2021

Services for Science and Education – United Kingdom

METHODOLOGY

This paper used commercial software in the Integrated Production Modelling (IPM) suite -

Production and Systems Performance Analysis (PROSPER) and General Allocation Package

(GAP) to model and examine two producing oil wells located in the Niger Delta using nodal

analysis. Production data from two wells operating in the Niger Delta were obtained and the

behavior of the wells were analyzed and gas lift was implemented at a later stage when the

wells were unable to flow naturally. The wells production performances were optimized using

continuous and intermittent gas lift systems. PROSPER was used to design the continuous and

intermittent gas lift systems for the wells and GAP was used to integrate the whole system for

production optimization. This involved an outline description of different methods applied and

the procedures undertaken to effectively arrived at the objectives of the study illustrated in

Figure 1 and 2.

Nodal Analysis

Nodal analysis was carried out to evaluate the performance of production wells and

subsequently evaluate the most viable option for optimizing the wells performance. It involves

specifying a nodal point, usually at the bottom hole or wellhead, and dividing the producing

system into two parts - the inflow and the outflow. The flow behavior, expressed as flow rate

vs. pressure, from the reservoir to the node is called Inflow, and from the node to the outlet,

fixed pressure point at the surface is called Outflow.