Developing sustainable energy policies for electrical energy conservation in Saudi Arabia

Towards the end of 1998, the Saudi Arabian electricity sector embarked upon a major restructuring program. One of the aims of the program is to achieve sustainable performance. Although progress has been made, a number of challenges remain, including high demand growth, low generation capacity reserve margins, inefficient energy use, absence of time-of-use tariffs, and the need for large capital investments to meet current and future expansion.     

Modelling industrial energy demand in Saudi Arabia

Between 1986 and 2016, industrial energy consumption in Saudi Arabia increased by tenfold, making it one of the largest end-use sectors in the Kingdom. Despite its importance, there appear to be no published econometric studies on aggregate industrial energy demand in Saudi Arabia. We model aggregate industrial energy demand in Saudi Arabia using Harvey’s (1989) Structural Time Series Model, showing that it is both price and income inelastic, with estimated long-run elasticities of −0.34 and 0.60, respectively. The estimated underlying energy demand trend suggests improvements in energy efficiency starting from 2010.Applying decomposition analysis to the estimated econometric equation highlights the prominent roles of the activity effect (the growth in industrial value added) and the structure effect (the shift towards energy-intensive production) in driving industrial energy demand growth. Moreover, the decomposition shows how exogenous factors such as energy efficiency helped mitigate some of that growth, delivering cumulative savings of 6.8 million tonnes of oil equivalent (Mtoe) between 2010 and 2016.Saudi Arabia implemented a broad energy price reform program in 2016, which raised electricity, fuel, and water prices for households and industry. The decomposition results reveal that, holding all else constant, higher industrial energy prices in 2016 reduced the sector’s energy consumption by 6.9 %, a decrease of around 3.0 Mtoe. Saudi policymakers could therefore build on the current policy of energy price reform and energy efficiency standards to mitigate the rate of growth of industrial energy consumption, increase economic efficiency, and maintain industrial sector competitiveness.     

Potentiality of daylighting in a maritime desert climate: the Eastern coast of Saudi Arabia

Energy savings from the utilization of daylight will be influenced by the amount of external daylight incident on the external surface of the window plane. Therefore, savings from daylight will vary from a place to another, based on the prevailing sky conditions in the climate concerned. This paper aims to investigate the potentiality of natural light if used a source of internal illuminance in buildings in the Eastern coast of Saudi Arabia. This includes providing information about daylight performance in the area.     

Gasoline demand in Saudi Arabia: are the price and income elasticities constant?

ABSTRACT

The paper investigates gasoline consumption in case of oil-exporting country applying Time-varying Coefficient Cointegration approach to the data from 1980 to 2017. Empirical estimations show that long-run income and price elasticities are not constant and are responsive to price and income fluctuations in the period considered. The income elasticity of gasoline demand increased until 2014, peaking at 0.151, following growth in disposable income, before declining to 0.136 in 2017. However, consumers do not stop driving when their disposable incomes fall, resulting in a less elastic response of gasoline demand to income. Price elasticities sit in the range of ?0.31 to ?0.05, becoming less elastic when prices are low and vice versa.

The findings of the study may be useful in successful implementation of energy price reforms and implementation of environmental policies.     

沙特钻修井技术

针对沙特油田产层开发特点,介绍了中原钻井在沙特钻井承包施工中采用的边漏边钻、边涌边钻、清水解卡、小井眼钻井、短半径水平井钻井、多底井钻井等先进技术,有效地降低了钻井成本,利用了每口井的资源,大大提高了单井产量,对国内钻修井技术的发展有一定参考作用。     

Load and energy requirements in residential buildings in Saudi Arabia: A comparative study

The load and energy requirements in residential buildings vary according to a number of factors. One of these factors is the geographical location in which the building is situated. Using a detached single-family house, the DOE2.1C load and energy analysis program was used to investigate the effect of the geographical location on the load and energy requirements. Four different cities, namely Dhahran, Riyadh, Jeddah and Khamis-Mushayt, representing four different climatic locations, are considered in this study. The analysis shows that the building parameters having the greatest impact on load are conduction through walls and roof, glazing area and infiltration level. The capacity requirements of the equipment and the total energy requirement for year-round air conditioning were calculated for a house in each city. A comparison shows that the city of Khamis-Mushayt has the lowest energy consumption and Jeddah has the highest energy consumption. The equivalent uniform annual cost (EUAC) method was also used to compare the economic performances of typical houses in the four cities. The comparison shows that the district of Khamis-Mushayt has the lowest EUAC, but the difference between the other cities is not significant. Furthermore, it shows that there is a significant difference between the government's and customers' EUACs.     

Applications of Thermal Energy Storage in Saudi Arabia

In Saudi Arabia, the heating, ventilating and air conditioning (HVAC) system typically accounts for 65% of the total electrical energy consumption in buildings. This is due to a very high ambient temperature which persists for a long period of time in a summer season. Moreover, gas turbines efficiency decrease also with the high ambient temperatures. In the HVAC industry cool storage, or commonly known as Thermal Energy Storage (TES) is the most preferred demand side management (DSM) technology for shifting cooling electrical demand from peak daytime periods to off‐peak night‐time. The most popular and well‐suited TES concept for Saudi Arabia is either chilled water or ice storage system, depending upon the applications and the required storage capacity. This paper shows how TES offers a means of reducing the electrical demand in large commercial buildings. Additionally, it is seen that efficiencies of the air cooled chillers are increased if they run overnight. Similarly efficiencies of gas turbine is also increased when a TES based pre‐cooled air is used as an inlet to the turbine. This paper also discusses favouring conditions and other aspects of cool storage applications in Saudi Arabia. TES economics are considered and a cost analysis is presented to illustrate the potential savings that can be achieved by the use of TES in Saudi Arabia. Copyright © 1999 John Wiley & Sons, Ltd.     

Wind energy resource assessment for five locations in Saudi Arabia

The analysis of recently collected wind data at five sites in Saudi Arabia namely, Dhulum, Arar, Yanbu, Gassim and Dhahran is presented. The five sites represent different geographically and climatologically conditions. The data collected over a period spanned between 1995 and 2002 with different collection periods for each site. Daily, monthly and frequency profiles of the wind speed at the sites showed that Dhulum and Arar sites have higher wind energy potential with annual wind speed average of 5.7 and 5.4 m/s and speeds higher than 5 m/s for 60 and 47% of the time, respectively. The two sites are candidates for remote area wind energy applications. The costal site's, i.e. Yanbu and Dhahran wind speed data indicated that the two sites have lower annual wind speed averages and wind blows at speed higher than 5 m/s during afternoon hours. That makes the two sites candidates for grid connected wind systems for electrical load peak shaving. The data of Gassim site showed that the site has the lowest wind energy potential compared to the others. The annual energy produced by a Nordex N43 wind machine is estimated to be 1080, 990, 730, 454 and 833 MWh for Dhulum, Arar, Yanbu, Gassim and Dhahran, respectively. The analysis showed that the estimated annual energy produced by the machine based on 10 min averaged data is 2.5% higher than the estimated energy based on 30 min averaged data.     

Performance and development of PV - plant for water pumping and desalination for remote area in Saudi Arabia

PV plant for water pumping and desalination in remote area has been implemented; the plant was the first of its kind in Saudi Arabia. The design of PV plant was based on the specification of the site, the depth and quality of water, the daily water quantity produced and the autonomy period of the plant during cloudy conditions as well as other local climatic conditions. The plant has two main PV separate systems, first, PV water pumping system which is characterized by storing the water in two storage tanks and without electric energy storage, second, PV system for the operation of the reverse osmosis unit (water desalination), this system is characterized by the storage of electric energy (batteries). The storage batteries are used to supply the required electric power to the equipment in the plant, during night and cloudy weather. The batteries capacity is designed to be sufficient for 5 days autonomy. In order to make the operation and maintenance of the PV plant highly reliable, the design is based on the selection of equipment which are commonly available in the local market. The head of the submersible pump is 50 m from surface level, and the amount of water production from Reverse Osmosis Unit is about 600 liters per hour. The total installed PV capacity for pumping system is 980 Wp, and for desalination system is 10. 89 kWp.     

Overview of energy storage systems for storing electricity from renewable energy sources in Saudi Arabia

Renewable power (photovoltaic, solar thermal or wind) is inherently intermittent and fluctuating. If renewable power has to become a major source of base-load dispatchable power, electricity storage systems of multi-MW capacity and multi-hours duration are indispensable. An overview of the advanced energy storage systems to store electrical energy generated by renewable energy sources is presented along with climatic conditions and supply demand situation of power in Saudi Arabia. Based on the review, battery features needed for the storage of electricity generated from renewable energy sources are: low cost, high efficiency, long cycle life, mature technology, withstand high ambient temperatures, large power and energy capacities and environmentally benign. Although there are various commercially available electrical energy storage systems (EESS), no single storage system meets all the requirements for an ideal EESS. Each EESS has a suitable application range.     

Aquifer thermal storage (ATES) for air-conditioning of a supermarket in Turkey

A heating, ventilation and air-conditioning (HVAC) system with integrated aquifer thermal energy storage (ATES) was designed for a supermarket building in Mersin, a city near the Mediterranean coast in Turkey (36° 49′ N and 34° 36′ E). This is the first ATES application carried out in Turkey. The peak cooling and heating loads of the building are 195 and 74 kW, respectively. The general objective of the system is to use the groundwater from the aquifer to cool down the condenser of the HVAC system and at the same time storing this waste heat in the aquifer. Cooling with groundwater at around 18 °C instead of utilizing outside summer air at 30–35 °C decreases consumption of electrical energy significantly. In addition, stored heat can be recovered when it is needed in winter. The HVAC system with ATES started operation in August 2001 in cooling mode with an average coefficient of performance (COP) of 4.18, which is almost 60% higher than a conventional system.     

Cost,footprint, and reliability implications of deploying hydrogen in off-grid electric vehicle charging stations: A GIS-assisted study for Riyadh,Saudi Arabia

For the first time, we quantify cost, footprint, and reliability implications of deploying hydrogen-based generation in off-grid electric vehicle charging stations (CS) using an optimization model coupled with a geographic information system (GIS) analysis for the city of Riyadh, Saudi Arabia. We also account for the challenges associated with wind energy deployment as a candidate generation technology within city centers. The analysis was restricted to carbon-free technologies: photovoltaics (PV), wind, battery, and hydrogen fuel-cells. At current prevailing technology costs, hydrogen can reduce the required footprint of off-grid CSs by 25% at a small incremental cost increase without impacting the charging reliability. By 2030, however, hydrogen will simultaneously provide the footprint and cost advantages. If we allow as little as 5% of the annual load to be unmet, the required footprint of the CS decreases by 60%. The levelized cost of energy values for the CS by 2030 can range between 0.13 and 0.20 $/kWh depending on learning-curve assumptions. The footprints calculated are then mapped to five land parcel categories in Riyadh: gas station, hospital, mall, school, and university. Incorporating hydrogen in CS design increases the number of parcels that could accommodate CSs by 15–45% via reducing the required PV array (i.e., footprint).     

冰蓄冷空调技术与上海电网调峰

论文详细介绍了上海电力的发展现状以及电力消费变化规律；分析了冰蓄冷空调技术的特点，随着空调负荷比重的增加，强调了冰蓄冷空调技术良好的削峰作用。推广冰蓄冷空调技术必将成为上海电力需求侧管理的重要手段。     

The established mega watt linear programming-based optimal power flow model applied to the real power 56-bus system in eastern province of Saudi Arabia

A current trend in electric power industries is the deregulation around the world. One of the questions arise during any deregulation process is: where will be the future generation expansion? In the present paper, the study is concentrated on the wheeling computational method as a part of mega watt (MW) linear programming-based optimal power flow (LP-based OPF) method. To observe the effects of power wheeling on the power system operations, the paper uses linear interactive & discrete optimizer (LINDO) optimizer software as a powerful tool for solving linear programming problems to evaluate the influence of the power wheeling. As well, the paper uses the optimization tool to solve the economic generation dispatch and transmission management problems. The transmission line flow was taken in consideration with some constraints discussed in this paper. The complete linear model of the MW LP-based OPF, which is used to know the future generation potential areas in any utility is proposed. The paper also explains the available economic load dispatch (ELD) as the basic optimization tool to dispatch the power system. It can be concluded in the present study that accuracy is expensive in terms of money and time and in the competitive market enough accuracy is needed without paying much.     

Industrial energy use-III. The prospects for providing motive power in a machine tool shop from a centralized hydraulic system

This paper describes a comparative economic study of electric and hydraulic power transmission. the data and results apply to a particular site, but the methodology is generally applicable. the study used mathematical models of the various components in electromechanical and hydraulic power transmission systems to determine in each case the necessary energy input to supply a specified load cycle at the machine tool spindle. the study concludes that a central hydraulic system on the site studied would operate with 20 per cent less energy consumption than the existing electromechanical system. the economic appraisal of the merits of electromechanical and hydraulic power distribution systems is dominated by capital savings in the final drives; these are assessed.     

Guidelines for Sizing Shading Devices for Typical Residential Houses in Muscat,Oman

Energy consumption of Oman＇s building sector is around 55% of the country＇s total energy demand and it has increased by 59% from 2005 to 2010. This paper investigates the potential of energy conservation in residential buildings in the city of Muscat by providing guidelines to reduce solar gain in overheated season. It aims to identify the problem of high energy consumption in modem houses and study the relationship between energy consumption and thermal performance of the building. Based on the authors＇ analysis of Oman＇s solar data, recommendations for shading devices were developed and evaluated using e-QUEST. An energy reduction of around 10% was achieved without drastically increasing the cost of construction while also taking into consideration of society＇s requirement for privacy and its concern to visually maintain cultural identity.     

Role of hydrogen storage in renewable energy management for Ontario

Effective energy storage and management is needed to manage intermittent renewable energy systems. Several jurisdictions around the world are planning to reduce or close their coal power plants to allow for renewable energy expansion, such as Ontario, Canada. Hydrogen storage, which is a promising energy storage option, is capable of meeting energy requirements that will arise from the shutdown of coal plants. In this paper, both economic and environmental feasibility of a hydrogen system linked with wind and hydroelectric plants in Ontario will be investigated. The Princefarm wind power plant and Beck1 hydro plant with production capacities of 189 MW and 490 MW, respectively, are analyzed in a case study for comparison purposes. The environmental analysis demonstrates the advantageous role of hydrogen storage and energy conversion. The overall system life-cycle yields 31.02 g CO₂ eq per 1 kW h power output of the system when hydrogen energy storage is adopted. The payback periods of the systems linked with the Princefarm and Beck1 are also analyzed and found to be about 17 years.     

Optimal operations for hydrogen-based energy storage systems in wind farms via model predictive control

Efficient energy production and consumption are fundamental points for reducing carbon emissions that influence climate change. Alternative resources, such as renewable energy sources (RESs), used in electricity grids, could reduce the environmental impact. Since RESs are inherently unreliable, during the last decades the scientific community addressed research efforts to their integration with the main grid by means of properly designed energy storage systems (ESSs). In order to highlight the best performance from these hybrid systems, proper design and operations are essential. The purpose of this paper is to present a so-called model predictive controller (MPC) for the optimal operations of grid-connected wind farms with hydrogen-based ESSs and local loads. Such MPC has been designed to take into account the operating and economical costs of the ESS, the local load demand and the participation to the electricity market, and further it enforces the fulfillment of the physical and the system's dynamics constraints. The dynamics of the hydrogen-based ESS have been modeled by means of the mixed-logic dynamic (MLD) framework in order to capture different behaviors according to the possible operating modes. The purpose is to provide a controller able to cope both with all the main physical and operating constraints of a hydrogen-based storage system, including the switching among different modes such as ON, OFF, STAND-BY and, at the same time, reduce the management costs and increase the equipment lifesaving. The case study for this paper is a plant under development in the north Norway. Numerical analysis on the related plant data shows the effectiveness of the proposed strategy, which manages the plant and commits the equipment so as to preserve the given constraints and save them from unnecessary commutation cycles.     

A novel peak load shaving algorithm via real‐time battery scheduling for residential distributed energy storage systems

As population grows and energy consumption increases, generation, transmission, and energy distribution costs also increase. Sudden and unpredicted demand increase at peak periods might lead to failure and even damage the power grid. This is a challenge for stability and reliability of the grid. Peak load shaving is considered as an effective approach while transition from peak load periods. In this paper, peak load shaving is modeled mathematically through storing energy on demand side and solved using optimization method. Using the results obtained from solving the optimization problem, a simple effective algorithm is proposed for peak load shaving via real‐time scheduling of distributed battery storage systems without complicated calculations. All characteristics required for systemic design of peak load shaving for residential, commercial, and industrial loads are presented. This method can be used in the presence of photovoltaic arrays or other renewable or nonrenewable distributed energy resources simultaneously, and it can be adapted to different conditions and demands. Here, real measured data of a residential state, an office building with photovoltaics, a hotel, and a small office are used for simulation, and GAMS is used for analysis.     

电力需求侧管理刍议

阐明了电力需求侧管理（ＤＳＭ）的基本概念,列举了国内外成功实施ＤＳＭ 的实例及采取的主要措施,并对ＤＳＭ 的计算机管理控制系统和各部分的功能作了简要介绍．