The Investment

Geological Exploration and Reserve Assessment

Before beginning oil extraction, it is essential to determine the location of deposits and their characteristics. This process involves geological exploration, which includes analyzing the structure of the Earth’s crust, identifying promising areas, and conducting a detailed study of geological formations. The primary method for locating oil reserves is seismic surveying, in which artificial seismic waves are sent into the ground, and their reflections are recorded by specialized equipment. This technique helps map underground structures and identify potential hydrocarbon reservoirs. Once promising zones have been detected, exploratory drilling is conducted. During this phase, rock samples—known as cores—are extracted and analyzed to determine the presence of hydrocarbons. Additionally, laboratory studies are carried out to assess the composition of the oil, the density of rock formations, and the presence of water. Based on these data, estimated oil reserves are calculated, and the economic feasibility of developing the field is evaluated. If the deposit is deemed profitable, preparations begin for full-scale extraction.

Oil Well Drilling

Drilling is a critical stage in oil production, allowing access to underground reservoirs. Different drilling techniques are used depending on the geological conditions and the location of the deposit. Vertical drilling is employed for simple reservoirs with direct access to oil-bearing layers. Directional drilling is used when extracting oil from hard-to-reach areas, such as beneath water bodies or urban zones. Horizontal drilling increases the contact area between the well and the oil-bearing formation, improving extraction efficiency. The drilling process begins with the installation of a drilling rig. The well is then gradually deepened using specialized drilling fluids that prevent wellbore collapse and cool the drilling equipment. As the well progresses, casing pipes are installed to reinforce the well walls and prevent water or gas intrusion. Once the drilling reaches the oil-bearing formation, perforation is carried out, allowing oil to flow into the wellbore. Afterward, the well is equipped with the necessary systems and mechanisms for lifting oil to the surface, such as pumps or gas-lift technology.

Oil Transportation and Storage

Once extracted, crude oil must be transported to refineries and consumers. The main transportation methods include pipelines, railway tank cars, marine tankers, and road transport. Pipelines are the most common mode of transport due to their efficiency and relatively low operating costs. However, in remote or challenging environments, such as the Arctic or the jungles of South America, alternative transport methods are required, including helicopters and specialized trucks. Before transportation, crude oil undergoes primary treatment to remove water, gases, and mechanical impurities. In some cases, particularly when dealing with heavy hydrocarbons, oil needs to be heated to reduce its viscosity, ensuring a smoother flow through pipelines. Proper storage is also crucial, requiring specially designed tanks that prevent leaks, contamination, and fire hazards. Safe and efficient oil transportation and storage are essential for maintaining supply chains and minimizing environmental risks.

REGULAR ROAD REPAIRS

Modern roads are embedded with sensors and intelligent systems that monitor traffic, weather conditions and pavement conditions in real time. This data allows traffic to be regulated quickly, maximizing safety and smooth traffic flow. Monitoring systems react instantly to changes such as rain or snow to alert drivers to challenging conditions and reduce the risk of accidents.

BRIDGES AND RAILWAYS

Bridges and railroads today are equipped with intelligent sensors that monitor load, vibration, weather conditions and pavement condition in real time. These systems react instantly to changes and warn of wear and tear or the need for repairs. For example, special sensors in bridges detect the slightest vibrations, and the system automatically sends information to the control center to prevent potential damage. Railroad tracks equipped with smart monitoring systems can adapt to changes in weather conditions, keeping traffic safety at the maximum level.

PIPELINES AND SEWERS

One of the most innovative technologies in pipeline and sewer construction is trenchless installation methods. Using techniques such as horizontal directional drilling (HDD) and microtunneling, engineers can lay pipes underground without destroying pavement or damaging the surrounding landscape. These methods minimize inconvenience to residents by reducing noise, construction waste and installation time. Trenchless technologies allow pipes to be laid in difficult locations, such as under rivers, roads and buildings.

CONSTRUCTION OF POWER PLANTS

Del Mar Energy pays special attention to the environmental sustainability of its facilities. Substations are equipped with systems to prevent leaks and minimize environmental impact. In some projects, the company integrates renewable energy sources, such as solar panels, to supply the substations' own needs.

INSTALLATION OF THERMAL POWER UNITS

Del Mar Energy is also committed to an environmentally friendly approach to fuel selection when building its thermal power plants. The company is gradually switching to cleaner fuels such as natural gas and biomass, which reduces its carbon footprint and emissions. Some power plants utilize combined heat and power sources to integrate renewable resources such as solar and wind installations, further reducing dependence on traditional fuels.

RECYCLING OF SECONDARY RAW MATERIALS

Del Mar Energy's plants utilize advanced automated sorting techniques, such as optical sensors and artificial intelligence systems that can accurately distinguish between material types. This allows plastic, metal, glass and other components to be separated with high precision and maximizes the yield of recycled raw materials. Thanks to these technologies, the company's plants minimize material loss and improve the quality of finished products, ensuring greener production.

SALE AND INSTALLATION OF SOLAR MODULES

Del Mar Energy designs and manufactures double-sided solar panels capable of capturing solar energy from both sides. These panels are particularly effective in environments where light is reflected from surfaces such as snow or water, increasing overall energy production.

WINDMILL CREATION

The company's wind turbines are equipped with intelligent monitoring systems that collect and analyze data on equipment operation in real time. Using artificial intelligence and machine learning technologies, the systems can predict possible failures and optimize operation. This allows preventive maintenance and troubleshooting before faults occur, which extends turbine life and minimizes operating costs.

GEOTHERMAL RESOURCE EXPLOITATION

Del Mar Energy actively uses closed-loop systems to develop its geothermal projects, which prevent groundwater leakage and minimize environmental impact. In these systems, fluid circulates in a closed loop, taking heat from the underground layers and returning it to the surface. Closed loop systems preserve the natural balance of groundwater, making geothermal plants more sustainable and environmentally friendly.

DEVELOPMENT OF MINERAL DEPOSITS

After mining, all Del Mar Energy Inc minerals undergo a beneficiation process that removes impurities, increases the concentration of the useful component and prepares the final products for industrial use. Modern beneficiation techniques include flotation, magnetic separation and chemical processes that enhance the quality of the raw material. These technologies not only produce high quality materials, but also reduce waste, making mining more environmentally friendly.

COAL MINING

Del Mar Energy Inc is implementing carbon capture and methane capture (CCUS) technologies to reduce its carbon footprint. These technologies collect carbon dioxide and methane emitted from coal mining and combustion and store it safely underground. This not only reduces greenhouse gas emissions, but also helps utilize methane as an additional energy source, turning it from a pollutant into a useful resource.

STEEL PRODUCTION

Del Mar Energy designs and manufactures equipment for the petrochemical industry, using state-of-the-art industrial technology to work with carbon, alloy and high-alloy corrosion-resistant steels. The company manufactures column equipment that is a key link in the production of a range of chemicals in adsorption and desorption processes, gas cooling and purification. The best steel alloys such as St3SP, St20, 09G2S, 12X18N10T, 08X18G8N2T, AISI 304, AISI 314, AISI 316, as well as heat-resistant chromium-molybdenum steel 12XM, 15XM are used in production.