Dajiya Nauyin – Mafi Yawan, Karkashin Aiki da Zabu Yawan Tushen

Za a nan Thermal Power Plant?

Hukumar da na iya kawo energy ya ce mai ban sha ko kawo, amma yana iya zama daga wani abu zuwa wani. Energy tsarin kaya, hasashen, za a iya kawo ita daga duk fadada sources of energy. Fadada da ake gina don kawo energy tsarin kaya a matsayin scale tafi, sunan su ne power plants ko kuma power stations.

Thermal power plant shine wata sabon fadin kawo energy da ke gina don kawo heat energy zuwa energy tsarin kaya. Heat energy wadannan plants za a iya shiga daga cikin sources of energy, tare da coal, diesel, biofuels, solar energy, da nuclear energy. Idan an yi amfani da hukumomi "thermal power plant" ta fi sani da plants da ke amfani da sources of heat, amma ana sanar da su a matsayin plants da ke amfani da coal don kawo heat. Saboda haka, thermal power plants suna da damar conventional power generation systems. Suna da sunan steam-turbine power plants ko kuma coal-fired power plants, wanda ke nuna primary fuel source da key energy-conversion mechanism da ake amfani da su.

Yadda Ake Gini Thermal Power Plant

Thermal power plants sun yi aiki da Rankine cycle, wata fundamental thermodynamic cycle don kawo heat zuwa mechanical work, wanda ake amfani da ita don kawo energy tsarin kaya. Diagram bayanai ko layout na wannan thermal power plant ya ba aiki da visual representation of its operational components and processes.

Aiki da Components of a Thermal Power Plant

Tattalin Aiki

Thermal power plants sun bukatar quantity mai yawa na fuel, musamman coal. Saboda volume mai yawa, coal suna daukan da trains don kawo ita zuwa dedicated fuel storage areas. A baya, raw coal ya fi yawa zuwa crusher, wanda ke kusa ita zuwa smaller, more manageable pieces before being conveyed to the boiler.

A cikin coal, water mai yawa shine mafi kyau don steam production within the boiler. Abubuwan da ake gudanar da water, suna da process of treatment. Ita suna shiga da filters to remove impurities and any dissolved air, ensuring its purity. Ba a gane, water ya shiga zuwa boiler drum. Inside the boiler drum, the heat generated by the combustion of coal is transferred to the water. As a result, the water undergoes a phase change and transforms into steam.

Steam produced is high-pressure and high-temperature, making it ideal for power generation. This steam is then channeled to a superheater, where it is further heated to increase its thermal energy. The superheated steam is subsequently directed towards the turbine blades. As the steam flows over the turbine blades, its thermal energy is converted into mechanical rotational energy by the turbine.

The turbine is mechanically coupled to an alternator via a common shaft. As the turbine rotates, it drives the rotor of the alternator. The alternator, in turn, converts this mechanical energy into electrical energy. To efficiently transmit the generated electrical energy over long distances, it is passed through a transformer, which steps up the voltage. The high-voltage electricity is then sent through transmission lines to reach the end-users, or loads, in the power grid.

After passing through the turbine, the steam, now at a lower pressure and temperature, is directed to a condenser. In the condenser, cold water circulates around the steam, causing it to condense back into its liquid state. This condensation process releases the remaining heat from the steam, effectively reducing its pressure and temperature. By recovering the water in this way, the efficiency of the power generation cycle is enhanced.

The condensed water is then pumped back to the boiler using a feedwater pump, ready to be heated and converted into steam once again, thus completing the cycle. Meanwhile, the ash generated as a by-product of coal combustion is removed from the boiler furnace. Proper disposal of this ash is crucial to prevent environmental damage. Additionally, during the combustion of coal in the boiler, flue gases are produced and are released into the atmosphere through the chimney.

Components Mai Yawa

A thermal power plant comprises several integral components that work in harmony to facilitate the power generation process:

• Boiler: The heart of the thermal power plant, where coal combustion occurs, and heat is transferred to water to produce steam.

• Turbine: Converts the thermal energy of high-pressure steam into mechanical rotational energy.

• Super-heater: Raises the temperature of the steam produced in the boiler, increasing its energy content for more efficient power generation.

• Condenser: Condenses the exhaust steam from the turbine back into water, recovering heat and maintaining the cycle's efficiency.

• Economizer: Preheats the feedwater using the heat from the flue gases, reducing the overall energy consumption of the boiler.

• Feedwater Pump: Circulates the condensed water from the condenser back to the boiler, ensuring a continuous supply for steam production.

• Alternator: Transforms the mechanical energy from the turbine into electrical energy, which can be distributed through the power grid.

• Chimney: Disperses the flue gases produced during coal combustion into the atmosphere in a controlled manner.

• Cooling Tower: Facilitates the cooling of the water used in the condenser, allowing it to be recycled and reused in the power generation process.

Components, Site Selection, and Efficiency of Thermal Power Plants

Key Components of Thermal Power Plants

Boiler

Pulverized coal, accompanied by preheated air, is fed into the boiler, which serves as the core component for generating high-pressure steam. Its primary function is to transform the chemical energy stored in coal into thermal energy through the combustion process. As coal burns inside the boiler, it generates intense heat, reaching temperatures sufficient to convert water into steam. The size of the boiler is directly determined by the heat requirements of the thermal power plant. There is a diverse range of boilers utilized in thermal power plants, including Haycock and wagon top boilers, firetube boilers, Cylindrical fire-tube boilers, and water-tube boilers, each with its own design characteristics and operational advantages.

Turbine

High-pressure and high-temperature superheated steam, produced by the boiler, is directed towards the turbine. When this steam strikes the turbine blades, it sets the turbine in motion. The turbine is a sophisticated mechanical device specifically engineered to convert the thermal energy of steam into rotational kinetic energy. Mechanically coupled to an alternator via a shaft, the turbine's rotation drives the alternator's rotor. Once the steam passes through the turbine, its temperature and pressure decrease, and it is then channeled to the condenser for further processing.

Super-heater

In a steam turbine-based power generation system, superheated steam is essential for efficient turbine operation. Wet and saturated steam, emerging from the boiler, is fed into the super-heater. This device plays a crucial role in transforming the steam into dry and superheated steam, significantly increasing its thermal energy content. Among all the components of a thermal power plant, the super-heater operates at the highest temperature. Three main types of superheaters are commonly employed: convection superheaters, which transfer heat through convection currents; radiant superheaters, which rely on radiant heat transfer; and separately fired superheaters. By enhancing the temperature of the steam generated by the boiler, the super-heater boosts the overall efficiency of the power generation process.

Condenser

After the steam has passed through the turbine and its temperature and pressure have dropped, the exhaust steam is recycled back into the power generation cycle. To optimize the turbine's efficiency, it is necessary to condense this steam, creating and maintaining a proper vacuum. The condenser achieves this by reducing the operating pressure, thereby increasing the vacuum level. This increase in vacuum causes the volume of steam to expand, allowing for more work to be extracted from the steam in the turbine. As a result, the overall efficiency of the power plant improves, with a corresponding increase in the turbine's output.

Economizer

The economizer is a specialized heat exchanger designed to minimize energy consumption within the power plant. Flue gases, rich in thermal energy, are exhausted from the boiler into the atmosphere. The economizer harnesses the heat from these flue gases to preheat the water. Water recovered from the condenser is pumped to the economizer by the feedwater pump. Here, it absorbs the heat from the flue gases, raising its temperature before entering the boiler. By reusing the waste heat of the flue gases, the economizer significantly enhances the overall efficiency of the power generation cycle.

Feedwater Pump

The feedwater pump is responsible for supplying water to the boiler. The water source can be either the condensed water from the condenser or fresh water. This pump increases the water pressure, ensuring a continuous and adequate supply to meet the boiler's requirements. Commonly, feedwater pumps are of the centrifugal or positive displacement type, each offering distinct advantages in terms of performance and efficiency.

Alternator

Mechanically connected to the turbine via a shared shaft, the alternator plays a pivotal role in the power generation process. As the turbine rotates under the force of the steam, it drives the alternator's rotor. This rotation induces an electromagnetic field, generating electrical energy. In essence, the alternator serves as a converter, transforming the kinetic energy of the turbine's rotation into electrical energy that can be transmitted and distributed through the power grid.

Chimney

In most thermal power plants that utilize coal as fuel, the combustion process in the boiler generates flue gases. The chimney provides a pathway for these flue gases to be safely discharged into the atmosphere. Its operation is based on the principles of natural draft and the stack effect. Hot air, being less dense, rises, creating a draft that draws the flue gases upwards. The height of the chimney is a critical factor; taller chimneys generate a stronger draft, facilitating more efficient gas dispersion.

Cooling Tower

True to its name, the cooling tower is primarily used to dissipate waste heat into the atmosphere. Employing various heat transfer methods, the cooling tower allows the heat from the water to evaporate, leaving behind cooler water that can be reused in the power generation cycle. Water condensed from the steam in the condenser is channeled to the cooling tower. Forced-flow cooling towers are commonly used in thermal power plants, where air is circulated from the bottom to the top of the tower, enhancing the heat transfer efficiency.

Site Selection Criteria for Thermal Power Plants

Availability of Fuel

Given that coal is the predominant fuel in most thermal power plants and the substantial quantity required for large-scale electricity generation, locating the power plant near a coal mine is highly advantageous. This proximity significantly reduces transportation costs, making the power generation process more economically viable.

Transportation Facility

Thermal power plants house numerous large-sized machinery and equipment. Therefore, the plant site must be selected in an area with excellent transportation infrastructure. Reliable rail or road transportation is essential for the efficient movement of coal, as well as for the delivery of new equipment and the transportation of workers, technicians, and engineers. Additionally, the availability of public transport in the vicinity ensures convenient access for the plant's workforce.

Availability of Water

A thermal power plant requires a massive amount of water to produce high-pressure and high-temperature steam. Consequently, the plant should be situated near a riverbank or in a location with a consistent and abundant water supply to meet the continuous demand for water used in steam generation and cooling processes.

Availability of Land

Constructing a thermal power plant demands a large expanse of land. Moreover, the land cost should be reasonable. When choosing the site, provisions for future expansion should also be considered. Since the plant houses heavy machinery, the ground must have sufficient load-bearing capacity, and a robust foundation is essential to support the equipment.

Distance from Populated Areas

Thermal power plants emit flue gases, ash, dust, and smoke during operation, all of which pose significant health risks to humans and can cause environmental damage to the surrounding atmosphere and land. To minimize these impacts, the plant should be located far from urban areas, residential communities, and agricultural farms. Additionally, the noise generated by the plant's machinery, such as alternators, transformers, fans, and turbines, further necessitates its placement in a remote location.

Ash Disposal Facility

Coal combustion results in the generation of ash, accounting for approximately 30-40% of the total coal consumption. Proper ash disposal is of utmost importance. Ash is collected from the bottom of the boiler furnace, and a significant portion of it is carried away by the flue gases. To manage ash effectively, two main ash-handling systems are employed: the bottom ash handling system and the fly ash handling system. The plant site should have suitable facilities for the safe and environmentally friendly disposal of this ash.

Proximity to Load Center

The electrical energy generated by the alternator is stepped up in voltage by a power transformer before being transmitted to the load center through transmission lines. Locating the thermal power plant near the load center reduces transmission costs and losses, ensuring a more efficient and cost-effective distribution of electricity.

Efficiency of Thermal Power Plants

In a thermal power plant, electricity generation involves multiple energy conversion stages. First, the chemical energy of coal is transformed into thermal energy. This thermal energy is then converted into kinetic or mechanical energy, which is finally converted into electrical energy. Due to these multiple energy conversion processes, the overall efficiency of thermal power plants is relatively low, typically ranging from 20-29%.

The efficiency of a thermal power plant is influenced by various factors, including the plant's size and the quality of coal used. A significant amount of heat energy is lost in the condenser during the power generation process. There are two primary types of efficiency metrics used to evaluate thermal power plants:

Thermal Efficiency

Thermal efficiency is defined as the ratio of the mechanical energy, expressed in heat equivalent terms, available at the turbine to the total heat energy released during the combustion of coal in the boiler. It measures the effectiveness of converting the heat energy from coal combustion into useful mechanical work in the turbine.

Thermal Efficiency

Thermal power plants typically achieve an approximate thermal efficiency of 30%. A significant portion, around 50% of the total heat energy generated, is dissipated as waste within the condenser. The remaining heat energy is lost through various other channels, such as in the flue gases emitted from the chimney and the ash produced during coal combustion. This substantial heat loss in the condenser and elsewhere underscores the inherent inefficiencies of traditional thermal power generation processes.

Overall Efficiency

The overall efficiency of a thermal power plant is calculated as the ratio of the heat equivalent of the electrical output to the total heat released during the combustion of coal. This metric provides a comprehensive measure of the plant's performance, encompassing all stages of energy conversion from the initial chemical energy stored in coal to the final electrical energy delivered to the grid. It reflects how effectively the plant can transform the energy in coal into usable electrical power, taking into account losses that occur at every step of the complex power generation process.

Overall Efficiency of Thermal Power Plants

The overall efficiency of a thermal power plant encapsulates all the losses that occur throughout the entire power-generation cycle. This includes inefficiencies during coal combustion, heat transfer processes, steam turbine operation, and crucially, the performance of the alternator, which converts mechanical energy into electrical energy. Each of these stages contributes to the overall energy loss, ultimately determining the proportion of the initial energy in the coal that is successfully transformed into usable electrical power.

The overall efficiency of a thermal power plant is closely tied to its size and power-generation capacity, typically measured in megawatts (MW). As a general rule, there is a direct correlation between the capacity of a thermal power plant and its efficiency: plants with lower capacities tend to exhibit lower overall efficiencies. Smaller plants often lack the economies of scale and optimized design features that larger plants possess, resulting in higher relative energy losses at each stage of the power-generation process. This means that a greater proportion of the energy from the fuel is wasted, reducing the amount of electricity that can be produced per unit of fuel consumed.