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Nitesh Kamerkar
Nitesh Kamerkar
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BOILERS Nitesh Dattaram Kamerkar  INTRODUCTION  WORKING PRINCIPLE  KEY COMPONENTS OF BOILERS  CLASSIFICATIONS  APPLICATIONS  CHALLENGES Overview of Boilers
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 1  INTRODUCTION TO BOILERS :- Boilers are pressure vessels designed to heat water or produce steam, which can then be used to provide space heating and/or service water heating to a building. In most commercial building heating applications, the heating source in the boiler is a natural gas fired burner. Oil fired burners and electric resistance heaters can be used as well. Steam is preferred over hot water in some applications, including absorption cooling, kitchens, laundries, sterilizers, and steam driven equipment. Boilers have several strengths that have made them a common feature of buildings. They have a long life, can achieve efficiencies up to 95% or greater, provide an effective method of heating a building, and in the case of steam systems, require little or no pumping energy. However, fuel costs can be considerable, regular maintenance is required, and if maintenance is delayed, repair can be costly. The pressure vessel of a boiler is usually made of steel (or alloy steel), or historically of wrought Iron. Stainless steel, especially of the austenitic types, is not used in wetted parts of boilers due to corrosion and stress corrosion cracking. However, ferritic stainless steel is often used in superheater sections that will not be exposed to boiling water, and electrically-heated stainless steel shell boilers are allowed under the European "Pressure Equipment Directive" for production of steam for sterilizers and disinfectors. In live steam models, copper or brass is often used because it is more easily fabricated in smaller size boilers. Historically, copper was often used for fireboxes (particularly for steam locomotives), because of its better formability and higher thermal conductivity; however, in more recent times, the high price of copper often makes this an uneconomic choice and cheaper substitutes (such as steel) are used instead. For much of the Victorian "age of steam", the only material used for boiler making was the highest grade of wrought iron, with assembly by riveting. This iron was often obtained from specialist iron works, such as at Cleator Moor (UK), noted for the high quality of their rolled plate and its suitability for high-reliability use in critical applications, such as high-pressure boilers. In the 20th century, design practice instead moved towards the use of steel, which is stronger and cheaper, with welded construction, which is quicker and requires less labor. It should be noted, however, that wrought iron boilers corrode far slower than their modern- day steel counterparts, and are less susceptible to localized pitting and stress-corrosion. This makes the longevity of older wrought-iron boilers far superior to those of welded steel boilers. Cast iron may be used for the heating vessel of domestic water heaters. Although such heaters are usually termed "boilers" in some countries, their purpose is usually to produce hot water, not steam, and so they run at low pressure and try to avoid actual boiling. The brittleness of cast iron makes it impractical for high-pressure steam boilers.
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 2  WORKING PRINCIPLE OF BOILERS :- Both gas and oil fired boilers use controlled combustion of the fuel to heat water. The key boiler components involved in this process are the burner, combustion chamber, heat exchanger, and controls. The burner mixes the fuel and oxygen together and, with the assistance of an ignition device, provides a platform for combustion. This combustion takes place in the combustion chamber, and the heat that it generates is transferred to the water through the heat exchanger. Controls regulate the ignition, burner firing rate, fuel supply, air supply, exhaust draft, water temperature, steam pressure, and boiler pressure. Hot water produced by a boiler is pumped through pipes and delivered to equipment throughout the building, which can include hot water coils in air handling units, service hot water heating equipment, and terminal units. Steam boilers produce steam that flows through pipes from areas of high pressure to areas of low pressure, unaided by an external energy source such as a pump. Steam utilized for heating can be directly utilized by steam using equipment or can provide heat through a heat exchanger that supplies hot water to the equipment. Fire tube Boiler (image source: www.hurstboiler.com)
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 3 A boiler is an enclosed vessel that provides a means for combustion heat to be transferred to water until it becomes heated water or steam. The hot water or steam under pressure is then usable for transferring the heat to a process. Water is a useful and inexpensive medium for transferring heat to a process. When water at atmospheric pressure is boiled into steam its volume increases about 1,600 times, producing a force that is almost as explosive as gun powder. This causes the boiler to be an equipment that must be treated with utmost care. The boiler system comprises of: a feed water system, steam system and fuel system. The feed water system provides water to the boiler and regulates it automatically to meet the steam demand. Various valves provide access for maintenance and repair. The steam system collects and controls the steam produced in the boiler. Steam is directed through a piping system to the point of use. Throughout the system, steam pressure is regulated using valves and checked with steam pressure gauges. The fuel system includes all equipment used to provide fuel to generate the necessary heat. The equipment required in the fuel system depends on the type of fuel used in the system. The water supplied to the boiler that is converted into steam is called feed water. The two sources of feed water are: 1. Condensate or condensed steam returned from the processes and 2. Makeup water (treated raw water) which must come from outside the boiler room and plant processes. For higher boiler efficiencies, an economizer preheats the feed water using the waste heat in the flue gas. Schematic Diagram of a Boiler Room
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 4  KEY COMPONENTS OF BOILERS :- Boilers are part of a hydronic heating system. Hydronic systems use water to transfer heat to a distribution source, like a radiator, to heat a home. Hydronic systems can heat via hot water or steam, depending on the type of boiler used. The boiler is the part of the system that heats the water to be distributed. The key elements of a boiler include the burner, combustion chamber, heat exchanger, exhaust stack, and controls. Boiler accessories including the flue gas economizer are also commonly used as an effective method to recover heat from a boiler. Key Components of Boilers are:-  Burner – The burner is the component of boiler that provides the heat that heats the water of system. The fuels used can be natural gas or oil.  Heat exchanger – The heat exchanger of boiler allows the heat from the burner to heat the water in system. The job of the heat exchanger is to carry the heat from the burner to the water without having direct contact with the water. It’s a similar idea to boiling water in a pot.  Supply lines – Hydronic heating systems use piping to deliver the heated water or steam to the distribution points, and the supply lines are the pipes that distribute the hot water or steam to distributor.  Return lines – When the water cools, or the steam cools and changes states back to water, the return lines bring this water back to the boiler for re-heating.  Firebox – The firebox is where the fuel of system meets the air, creating a flame.  Refractory – Refractory actually refers to refractory materials that are used for filling any gaps and/or openings that may be around the fire box – this helps ensure the fire stays in the fire box.  Circulator pumps – circulator pumps push the hot water or steam from system to the heat distributors in our homes.  Deaerators/Condenser - Deaerator and condenser tanks are only used in steam boiler systems and not in hot water and hot oil boil because here the fluid always is on liquid form. The construction of these two types of tanks is almost identical, but as their names suggest, they are used for different purposes. Two primary principles are used with this form of tank design: thermal and vacuum. This depends on which type of boiler being used. Each principle also has different pump construction requirements. Thermo principle A tank using the thermal principle is connected to the atmosphere. This design is normally used in smaller plants. Here, steam is used to maintain tank water temperature at around 105°C, which removes air from the water. Vacuum principle
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 5 Here, an ejector pump is used to create a vacuum in the tank. This causes the tank water to start boiling because of the low temperature, which in turn removes air from the water. This principle is normally used for steam turbine applications.  Economizer Historically, economizers have only been used in large-scale power plants. However, the demand for more efficient boilers within industry and marine means that economizers are now far more commonplace. An economizer is a heat exchanger that is placed in the exhaust from a boiler or in the exhaust funnel of the main engine of a ship. Pump requirements differ greatly, depending on where the economizer is installed.  Superheater It is integral part of boiler and is placed in the path of hot flue gases from the furnace. The heat recovered from the flue gases is used in superheating the steam before entering into the turbine (i.e. prime mover).Its main purpose is to increase the temperature of saturated steam without raising its pressure. Deaerator :- A deaerator is used to reduce oxygen (O2) and carbonic acid (CO2) levels in boiler feed water to protect a boiler against corrosion. It is possible to reduce oxygen and carbonic acid levels to about < 0.02 mg/l of O2 and 0 mg/l of CO2, depending on deaerator construction. Condenser :- A condenser ensures that all steam is condensed before being pumped back into the deaerator and on into the boiler. New treated water is normally fed into the condenser.
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 6 Natural gas boilers employ one of two types of burners, atmospheric burners, also called natural draft burners and forced draft burners, also called power burners. Due to more stringent air quality regulations, low NOx burners and pre-mix burners are becoming more commonly used and even required in some areas. By ensuring efficient mixing of air and fuel as it enters the burner, these types of burners can ensure that NOx emissions are reduced. The combustion chamber, usually made of cast iron or steel, houses the burners and combustion process. Temperatures inside the combustion chamber can reach several hundred degrees very quickly. Heat exchangers may be made from cast iron, steel tube bundles, or, in the case of some smaller boilers, copper or copper-clad steel. The exhaust stack or flue is the piping that conveys the hot combustion gasses away from the boiler to the outside. Typically this piping is made of steel, but in the case of condensing boilers it needs to be constructed of stainless steel to handle the corrosive condensate. Another consideration is whether the exhaust stack will be under a positive or negative pressure. This can determine how the joints of the exhaust stack must be sealed. Boiler controls help produce hot water or steam in a regulated, efficient, and safe manner. Combustion and operating controls regulate the rate of fuel use to meet the demand. The main operating control monitors hot water temperature or steam pressure and sends a signal to control the firing rate, the rate at which fuel and air enters the burner. Common burner firing sequences include on/off, high/low/off and modulating. Boiler safety controls include high pressure and temperature, high and low gas/oil pressure, and high and low water level and flame safeguard controls. These controls are considered safeties or limits that break the electrical circuit to prevent firing of the boiler. For example, if the event pressure in the boiler exceeds the pressure limit setting, the fuel valve is closed to prevent an unsafe, high pressure condition. The safety circuit of a flame safeguard control system typically includes switch contacts for low water cutoff, high limits, air providing switches, redundant safety and operating controls, and flame detectors. Flame detectors often consist of flame rods, and ultraviolet or infrared scanners to monitor the flame condition and deactivate the burner in the event of a non-ignition or other unsafe condition. Flame safeguard controls are programmed to operate the burner and cycle it through the stages of operation.
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 7  CLASSIFICATIONS OF BOILERS :- Boilers are classified into different types based on their working pressure and temperature, fuel type, draft method, size and capacity, and whether they condense the water vapor in the combustion gases. Boilers are also sometimes described by their key components, such as heat exchanger materials or tube design. Two primary types of boilers include Fire- tube and Water- tube boilers. In a Fire-tube boiler, hot gases of combustion flow through a series of tubes surrounded by water. Alternatively, in a water - tube boiler, water flows in the inside of the tubes and the hot gases from combustion flow around the outside of the tubes. Fire tube boilers are more commonly available for low pressure steam or hot water applications, and are available in sizes ranging from 500,000 to 75,000,000 BTU input. Water- tube boilers are primarily used in higher pressure steam applications and are used extensively for comfort heating applications. They typically range in size from 500,000 to more than 20,000,000 BTU input. Cast iron sectional boilers are another type of boiler commonly used in commercial space heating applications. These types of boilers don’t use tubes. Instead, they’re built up from cast iron sections that have water and combustion gas passages. The iron castings are bolted together, similar to an old steam radiator. The sections are sealed together by gaskets. They’re available for producing steam or hot water, and are available in sizes ranging from 35,000 to 14,000,000 BTU input. Cast iron sectional boilers are advantageous because they can be assembled on site, allowing them to be transported through doors and smaller openings. Their main disadvantage is that because the sections are sealed together with gaskets, they are prone to leakage as the gaskets age and are attacked by boiler treatment chemicals. Some of the well- known Boilers are:–  Babcock & Wilcox boiler  Cochran boiler - A vertical boiler with horizontal fire-tubes.  Cornish boiler - A large horizontal stationary boiler with a single flue.  La Mont boiler - A forced-water-circulation boiler. They are often used as marine heat-recovery boilers. It was also used, unsuccessfully, for an experimental steam locomotive in East Germany in the 1950s.  Lancashire boiler - A development of the Cornish boiler, with two flues.
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 8 BOILERS (According to Firing Method) Grate Firing Traveling grate stoker firing Front fired Burner Tangential fired Opposed jet firing Down- jet firing Cyclone firing BOILERS (According to Energy Source) Coal Liquid Fuel Gas Solid waste Biomass Recovery Fuel (RDF) Waste heat Nuclear Fuel
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 9 BOILERS (According to Use of Steam) Utility ( Electricity) Industrial Cogeneration Naval Marine Domestic heating Cooking BOILERS (According to Type of construction) Packaged shell(FireTube) Packaged water tube Field erected BOILERS (According to Type of water circulation) Natural Forced Combined
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 10  APPLICATIONS OF BOILERS :- Heat is basis of our life. If heat came only from the sun’s rays, large areas of the earth would be uninhabitable for man. Artificial heating (thermal heat) is therefore necessary, depending on the geographic position and season of the year. In addition to this, there are also a great number of technical processes that are only made possible through heat, for example, cooking, boiling and cleaning processes in the food and drink industry. But in many other branches, too, such as the paper, building, chemical or textile industry, many processes function only with heat (process heat). Industrial hot water boiler systems for generating thermal heat are very similar to the household heating boilers in our cellars. The main difference is that industrial boilers are dimensioned significantly larger, so their heating capacity is not only sufficient for a family home but also for hotels, hospitals, skyscrapers, industrial buildings or entire districts. When using process heat generated by steam boiler systems the individual applications are far more versatile. They are used in many industry sectors. Laundries and cleaning firms This is an obvious example of what steam is used for. It is just easier to get rid of spots and dirt when the washing water is heated. Our washing machine at home does the same, however with electrical heating. In large laundries this would be inefficient as electrical energy is too expensive. Steam can also be perfectly used for downstream processes like pressing, using the mangle, ironing or finishing. We know this process from steam-ironing at home; steam simply removes all creases. Food Industry Food must often be heated or boiled during processing. Thus this industrial sector obviously needs plenty of thermal energy. However, some steam applications are still stunning; a good example is potato processing. Breweries Most people know that a good and tasty beer consists of hops, malt and water. However, before enjoying the beer there is a complex production process. Malt has to be ground Cold potatoes are filled in a big pressure vessel and hot steam is abruptly injected. The abrupt heat supply causes the potato peels to fall off so they do not have to be peeled by hand any more. Now, isn’t it tempting to fetch the old steam cleaner from the cellar and use it as a cooking aid?
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 11 coarsely and mixed with water. The brewer calls this mashing. The mash must be heated to various temperatures in two to four hours. Steam generated with the steam boiler is normally used as a heat carrier. Subsequently, hops are added and the mixture has to cool down. Then yeast is added and triggers the fermentation so that the beer gets the desired effect. Again after bottles or barrels have been emptied they are normally returned to the brewery. Of course the breweries first have to clean them before they can be refilled. For this process steam is again required to heat up the water needed for cleaning. Building materials industry Large amounts of steam are also necessary for the production of molded bricks. The basic materials like sand, lime, water, etc. are mixed and pressed to relatively loose stone compounds. Subsequently, the stones are transported to a huge pressure vessel (autoclave) which is then closed and steam is injected. The stones have to harden at a temperature of approximately 200 °C and a pressure of about 16 bar for a certain period of time and can then be withdrawn as finished stones. Sewer pipe rehabilitation What to do if there is a drain leakage? This problem can either be solved by means of excavation works at the underground pipes and renewal of the sewage pipe systems or with rehabilitation tubes. These tubes are overdimensioned hoses that are inserted in the pipes without excavation work and then inflated with steam. The plastic hose attaches itself to the sewage pipe under application of pressure and temperature and the pipe can continue to be used for many years. …… and many other Industries  Electrical industry  Food packaging industry  Glass fibre production  Hospitals  Metal-working industry  Paper industry  Pharmaceutical industry  Plastics manufacturing  Primary industry  Print offices  Refineries  Steel works  Tank farms  Tobacco industry  Tyre manufacturing  Vulcanisation  Waste disposal  Waste incineration  Slaughterhouses  Agriculture  Animal food industry  Automotive industry  Bakeries  Ceramic industry  Cheese dairies  Dairies  Distilleries  Fruit processing  Dyeing factories  Chemical industry 
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 12  CHALLENGES IN BOILERS :-  Some of the major Challenges in Boilers are :- o To minimize size and weight. o To meet required life. o To be resistant to fouling and corrosion. o To minimize cost.  Poor Maintenance Statistics indicates that about two-thirds of all boiler failures and nearly all unscheduled shutdowns are caused by poor maintenance and operation.  Scaling Scale formations in boilers are responsible for lost efficiency, increased maintenance and operating costs not to mention lost revenue due to outages and downtime. Most scale formations in boilers occur due to the presence of hardness in the make-up water. This hardness reacts in the high temperatures environment within the boiler to form and insoluble scale. This insoluble scale coats the heat transfer surfaces, acting as an insulator to impede heat transfer. Hardness isn't the only cause of scale formation in boilers, other impurities such as iron, silica, copper, oil, etc. are often found in samples of boiler scale. In fact, it is rare to find scale which isn't the result of several of these impurities.  Slagging and Fouling Slagging occurs in boiler furnaces where ash deposits are exposed to the radiant heat of the coal flames, while fouling occurs in the boiler’s convective passes. Slagging & fouling are mainly observed in coal- fired boilers. Excessive ash deposits on a coal fired boiler’s heat transfer surfaces will reduce its efficiency, and in extreme cases a boiler can be shut down by ash related problems. It Slag on platen superheater tubes
BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 13 has been estimated that slagging incidents cost the global utility industry several billion dollars annually in reduced power generation and equipment maintenance.  Corrosion Corrosion occurs in boilers due to two major reasons. The most common cause is dissolved oxygen entering the system via the feed-water. Another common cause of corrosion in boiler systems is low pH within the boiler. This reduced pH may result from carbon dioxide infiltration or form contamination by other chemicals. The oxygen causes very localized corrosion to occur in the form of pitting. The pits are small but deep pinpoint holes which eventually can penetrate tube walls and cause their failure. Oxygen corrosion is normally controlled by driving the oxygen from the feed-water in a deaerating heater/deaerator or by chemically removing it with an oxygen scavenger such as sodium sulfite. There are many contaminates which can infiltrate a boiler system and cause low pH levels to develop.

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Boilers_report_final

  • 1. BOILERS Nitesh Dattaram Kamerkar  INTRODUCTION  WORKING PRINCIPLE  KEY COMPONENTS OF BOILERS  CLASSIFICATIONS  APPLICATIONS  CHALLENGES Overview of Boilers
  • 2. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 1  INTRODUCTION TO BOILERS :- Boilers are pressure vessels designed to heat water or produce steam, which can then be used to provide space heating and/or service water heating to a building. In most commercial building heating applications, the heating source in the boiler is a natural gas fired burner. Oil fired burners and electric resistance heaters can be used as well. Steam is preferred over hot water in some applications, including absorption cooling, kitchens, laundries, sterilizers, and steam driven equipment. Boilers have several strengths that have made them a common feature of buildings. They have a long life, can achieve efficiencies up to 95% or greater, provide an effective method of heating a building, and in the case of steam systems, require little or no pumping energy. However, fuel costs can be considerable, regular maintenance is required, and if maintenance is delayed, repair can be costly. The pressure vessel of a boiler is usually made of steel (or alloy steel), or historically of wrought Iron. Stainless steel, especially of the austenitic types, is not used in wetted parts of boilers due to corrosion and stress corrosion cracking. However, ferritic stainless steel is often used in superheater sections that will not be exposed to boiling water, and electrically-heated stainless steel shell boilers are allowed under the European "Pressure Equipment Directive" for production of steam for sterilizers and disinfectors. In live steam models, copper or brass is often used because it is more easily fabricated in smaller size boilers. Historically, copper was often used for fireboxes (particularly for steam locomotives), because of its better formability and higher thermal conductivity; however, in more recent times, the high price of copper often makes this an uneconomic choice and cheaper substitutes (such as steel) are used instead. For much of the Victorian "age of steam", the only material used for boiler making was the highest grade of wrought iron, with assembly by riveting. This iron was often obtained from specialist iron works, such as at Cleator Moor (UK), noted for the high quality of their rolled plate and its suitability for high-reliability use in critical applications, such as high-pressure boilers. In the 20th century, design practice instead moved towards the use of steel, which is stronger and cheaper, with welded construction, which is quicker and requires less labor. It should be noted, however, that wrought iron boilers corrode far slower than their modern- day steel counterparts, and are less susceptible to localized pitting and stress-corrosion. This makes the longevity of older wrought-iron boilers far superior to those of welded steel boilers. Cast iron may be used for the heating vessel of domestic water heaters. Although such heaters are usually termed "boilers" in some countries, their purpose is usually to produce hot water, not steam, and so they run at low pressure and try to avoid actual boiling. The brittleness of cast iron makes it impractical for high-pressure steam boilers.
  • 3. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 2  WORKING PRINCIPLE OF BOILERS :- Both gas and oil fired boilers use controlled combustion of the fuel to heat water. The key boiler components involved in this process are the burner, combustion chamber, heat exchanger, and controls. The burner mixes the fuel and oxygen together and, with the assistance of an ignition device, provides a platform for combustion. This combustion takes place in the combustion chamber, and the heat that it generates is transferred to the water through the heat exchanger. Controls regulate the ignition, burner firing rate, fuel supply, air supply, exhaust draft, water temperature, steam pressure, and boiler pressure. Hot water produced by a boiler is pumped through pipes and delivered to equipment throughout the building, which can include hot water coils in air handling units, service hot water heating equipment, and terminal units. Steam boilers produce steam that flows through pipes from areas of high pressure to areas of low pressure, unaided by an external energy source such as a pump. Steam utilized for heating can be directly utilized by steam using equipment or can provide heat through a heat exchanger that supplies hot water to the equipment. Fire tube Boiler (image source: www.hurstboiler.com)
  • 4. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 3 A boiler is an enclosed vessel that provides a means for combustion heat to be transferred to water until it becomes heated water or steam. The hot water or steam under pressure is then usable for transferring the heat to a process. Water is a useful and inexpensive medium for transferring heat to a process. When water at atmospheric pressure is boiled into steam its volume increases about 1,600 times, producing a force that is almost as explosive as gun powder. This causes the boiler to be an equipment that must be treated with utmost care. The boiler system comprises of: a feed water system, steam system and fuel system. The feed water system provides water to the boiler and regulates it automatically to meet the steam demand. Various valves provide access for maintenance and repair. The steam system collects and controls the steam produced in the boiler. Steam is directed through a piping system to the point of use. Throughout the system, steam pressure is regulated using valves and checked with steam pressure gauges. The fuel system includes all equipment used to provide fuel to generate the necessary heat. The equipment required in the fuel system depends on the type of fuel used in the system. The water supplied to the boiler that is converted into steam is called feed water. The two sources of feed water are: 1. Condensate or condensed steam returned from the processes and 2. Makeup water (treated raw water) which must come from outside the boiler room and plant processes. For higher boiler efficiencies, an economizer preheats the feed water using the waste heat in the flue gas. Schematic Diagram of a Boiler Room
  • 5. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 4  KEY COMPONENTS OF BOILERS :- Boilers are part of a hydronic heating system. Hydronic systems use water to transfer heat to a distribution source, like a radiator, to heat a home. Hydronic systems can heat via hot water or steam, depending on the type of boiler used. The boiler is the part of the system that heats the water to be distributed. The key elements of a boiler include the burner, combustion chamber, heat exchanger, exhaust stack, and controls. Boiler accessories including the flue gas economizer are also commonly used as an effective method to recover heat from a boiler. Key Components of Boilers are:-  Burner – The burner is the component of boiler that provides the heat that heats the water of system. The fuels used can be natural gas or oil.  Heat exchanger – The heat exchanger of boiler allows the heat from the burner to heat the water in system. The job of the heat exchanger is to carry the heat from the burner to the water without having direct contact with the water. It’s a similar idea to boiling water in a pot.  Supply lines – Hydronic heating systems use piping to deliver the heated water or steam to the distribution points, and the supply lines are the pipes that distribute the hot water or steam to distributor.  Return lines – When the water cools, or the steam cools and changes states back to water, the return lines bring this water back to the boiler for re-heating.  Firebox – The firebox is where the fuel of system meets the air, creating a flame.  Refractory – Refractory actually refers to refractory materials that are used for filling any gaps and/or openings that may be around the fire box – this helps ensure the fire stays in the fire box.  Circulator pumps – circulator pumps push the hot water or steam from system to the heat distributors in our homes.  Deaerators/Condenser - Deaerator and condenser tanks are only used in steam boiler systems and not in hot water and hot oil boil because here the fluid always is on liquid form. The construction of these two types of tanks is almost identical, but as their names suggest, they are used for different purposes. Two primary principles are used with this form of tank design: thermal and vacuum. This depends on which type of boiler being used. Each principle also has different pump construction requirements. Thermo principle A tank using the thermal principle is connected to the atmosphere. This design is normally used in smaller plants. Here, steam is used to maintain tank water temperature at around 105°C, which removes air from the water. Vacuum principle
  • 6. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 5 Here, an ejector pump is used to create a vacuum in the tank. This causes the tank water to start boiling because of the low temperature, which in turn removes air from the water. This principle is normally used for steam turbine applications.  Economizer Historically, economizers have only been used in large-scale power plants. However, the demand for more efficient boilers within industry and marine means that economizers are now far more commonplace. An economizer is a heat exchanger that is placed in the exhaust from a boiler or in the exhaust funnel of the main engine of a ship. Pump requirements differ greatly, depending on where the economizer is installed.  Superheater It is integral part of boiler and is placed in the path of hot flue gases from the furnace. The heat recovered from the flue gases is used in superheating the steam before entering into the turbine (i.e. prime mover).Its main purpose is to increase the temperature of saturated steam without raising its pressure. Deaerator :- A deaerator is used to reduce oxygen (O2) and carbonic acid (CO2) levels in boiler feed water to protect a boiler against corrosion. It is possible to reduce oxygen and carbonic acid levels to about < 0.02 mg/l of O2 and 0 mg/l of CO2, depending on deaerator construction. Condenser :- A condenser ensures that all steam is condensed before being pumped back into the deaerator and on into the boiler. New treated water is normally fed into the condenser.
  • 7. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 6 Natural gas boilers employ one of two types of burners, atmospheric burners, also called natural draft burners and forced draft burners, also called power burners. Due to more stringent air quality regulations, low NOx burners and pre-mix burners are becoming more commonly used and even required in some areas. By ensuring efficient mixing of air and fuel as it enters the burner, these types of burners can ensure that NOx emissions are reduced. The combustion chamber, usually made of cast iron or steel, houses the burners and combustion process. Temperatures inside the combustion chamber can reach several hundred degrees very quickly. Heat exchangers may be made from cast iron, steel tube bundles, or, in the case of some smaller boilers, copper or copper-clad steel. The exhaust stack or flue is the piping that conveys the hot combustion gasses away from the boiler to the outside. Typically this piping is made of steel, but in the case of condensing boilers it needs to be constructed of stainless steel to handle the corrosive condensate. Another consideration is whether the exhaust stack will be under a positive or negative pressure. This can determine how the joints of the exhaust stack must be sealed. Boiler controls help produce hot water or steam in a regulated, efficient, and safe manner. Combustion and operating controls regulate the rate of fuel use to meet the demand. The main operating control monitors hot water temperature or steam pressure and sends a signal to control the firing rate, the rate at which fuel and air enters the burner. Common burner firing sequences include on/off, high/low/off and modulating. Boiler safety controls include high pressure and temperature, high and low gas/oil pressure, and high and low water level and flame safeguard controls. These controls are considered safeties or limits that break the electrical circuit to prevent firing of the boiler. For example, if the event pressure in the boiler exceeds the pressure limit setting, the fuel valve is closed to prevent an unsafe, high pressure condition. The safety circuit of a flame safeguard control system typically includes switch contacts for low water cutoff, high limits, air providing switches, redundant safety and operating controls, and flame detectors. Flame detectors often consist of flame rods, and ultraviolet or infrared scanners to monitor the flame condition and deactivate the burner in the event of a non-ignition or other unsafe condition. Flame safeguard controls are programmed to operate the burner and cycle it through the stages of operation.
  • 8. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 7  CLASSIFICATIONS OF BOILERS :- Boilers are classified into different types based on their working pressure and temperature, fuel type, draft method, size and capacity, and whether they condense the water vapor in the combustion gases. Boilers are also sometimes described by their key components, such as heat exchanger materials or tube design. Two primary types of boilers include Fire- tube and Water- tube boilers. In a Fire-tube boiler, hot gases of combustion flow through a series of tubes surrounded by water. Alternatively, in a water - tube boiler, water flows in the inside of the tubes and the hot gases from combustion flow around the outside of the tubes. Fire tube boilers are more commonly available for low pressure steam or hot water applications, and are available in sizes ranging from 500,000 to 75,000,000 BTU input. Water- tube boilers are primarily used in higher pressure steam applications and are used extensively for comfort heating applications. They typically range in size from 500,000 to more than 20,000,000 BTU input. Cast iron sectional boilers are another type of boiler commonly used in commercial space heating applications. These types of boilers don’t use tubes. Instead, they’re built up from cast iron sections that have water and combustion gas passages. The iron castings are bolted together, similar to an old steam radiator. The sections are sealed together by gaskets. They’re available for producing steam or hot water, and are available in sizes ranging from 35,000 to 14,000,000 BTU input. Cast iron sectional boilers are advantageous because they can be assembled on site, allowing them to be transported through doors and smaller openings. Their main disadvantage is that because the sections are sealed together with gaskets, they are prone to leakage as the gaskets age and are attacked by boiler treatment chemicals. Some of the well- known Boilers are:–  Babcock & Wilcox boiler  Cochran boiler - A vertical boiler with horizontal fire-tubes.  Cornish boiler - A large horizontal stationary boiler with a single flue.  La Mont boiler - A forced-water-circulation boiler. They are often used as marine heat-recovery boilers. It was also used, unsuccessfully, for an experimental steam locomotive in East Germany in the 1950s.  Lancashire boiler - A development of the Cornish boiler, with two flues.
  • 9. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 8 BOILERS (According to Firing Method) Grate Firing Traveling grate stoker firing Front fired Burner Tangential fired Opposed jet firing Down- jet firing Cyclone firing BOILERS (According to Energy Source) Coal Liquid Fuel Gas Solid waste Biomass Recovery Fuel (RDF) Waste heat Nuclear Fuel
  • 10. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 9 BOILERS (According to Use of Steam) Utility ( Electricity) Industrial Cogeneration Naval Marine Domestic heating Cooking BOILERS (According to Type of construction) Packaged shell(FireTube) Packaged water tube Field erected BOILERS (According to Type of water circulation) Natural Forced Combined
  • 11. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 10  APPLICATIONS OF BOILERS :- Heat is basis of our life. If heat came only from the sun’s rays, large areas of the earth would be uninhabitable for man. Artificial heating (thermal heat) is therefore necessary, depending on the geographic position and season of the year. In addition to this, there are also a great number of technical processes that are only made possible through heat, for example, cooking, boiling and cleaning processes in the food and drink industry. But in many other branches, too, such as the paper, building, chemical or textile industry, many processes function only with heat (process heat). Industrial hot water boiler systems for generating thermal heat are very similar to the household heating boilers in our cellars. The main difference is that industrial boilers are dimensioned significantly larger, so their heating capacity is not only sufficient for a family home but also for hotels, hospitals, skyscrapers, industrial buildings or entire districts. When using process heat generated by steam boiler systems the individual applications are far more versatile. They are used in many industry sectors. Laundries and cleaning firms This is an obvious example of what steam is used for. It is just easier to get rid of spots and dirt when the washing water is heated. Our washing machine at home does the same, however with electrical heating. In large laundries this would be inefficient as electrical energy is too expensive. Steam can also be perfectly used for downstream processes like pressing, using the mangle, ironing or finishing. We know this process from steam-ironing at home; steam simply removes all creases. Food Industry Food must often be heated or boiled during processing. Thus this industrial sector obviously needs plenty of thermal energy. However, some steam applications are still stunning; a good example is potato processing. Breweries Most people know that a good and tasty beer consists of hops, malt and water. However, before enjoying the beer there is a complex production process. Malt has to be ground Cold potatoes are filled in a big pressure vessel and hot steam is abruptly injected. The abrupt heat supply causes the potato peels to fall off so they do not have to be peeled by hand any more. Now, isn’t it tempting to fetch the old steam cleaner from the cellar and use it as a cooking aid?
  • 12. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 11 coarsely and mixed with water. The brewer calls this mashing. The mash must be heated to various temperatures in two to four hours. Steam generated with the steam boiler is normally used as a heat carrier. Subsequently, hops are added and the mixture has to cool down. Then yeast is added and triggers the fermentation so that the beer gets the desired effect. Again after bottles or barrels have been emptied they are normally returned to the brewery. Of course the breweries first have to clean them before they can be refilled. For this process steam is again required to heat up the water needed for cleaning. Building materials industry Large amounts of steam are also necessary for the production of molded bricks. The basic materials like sand, lime, water, etc. are mixed and pressed to relatively loose stone compounds. Subsequently, the stones are transported to a huge pressure vessel (autoclave) which is then closed and steam is injected. The stones have to harden at a temperature of approximately 200 °C and a pressure of about 16 bar for a certain period of time and can then be withdrawn as finished stones. Sewer pipe rehabilitation What to do if there is a drain leakage? This problem can either be solved by means of excavation works at the underground pipes and renewal of the sewage pipe systems or with rehabilitation tubes. These tubes are overdimensioned hoses that are inserted in the pipes without excavation work and then inflated with steam. The plastic hose attaches itself to the sewage pipe under application of pressure and temperature and the pipe can continue to be used for many years. …… and many other Industries  Electrical industry  Food packaging industry  Glass fibre production  Hospitals  Metal-working industry  Paper industry  Pharmaceutical industry  Plastics manufacturing  Primary industry  Print offices  Refineries  Steel works  Tank farms  Tobacco industry  Tyre manufacturing  Vulcanisation  Waste disposal  Waste incineration  Slaughterhouses  Agriculture  Animal food industry  Automotive industry  Bakeries  Ceramic industry  Cheese dairies  Dairies  Distilleries  Fruit processing  Dyeing factories  Chemical industry 
  • 13. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 12  CHALLENGES IN BOILERS :-  Some of the major Challenges in Boilers are :- o To minimize size and weight. o To meet required life. o To be resistant to fouling and corrosion. o To minimize cost.  Poor Maintenance Statistics indicates that about two-thirds of all boiler failures and nearly all unscheduled shutdowns are caused by poor maintenance and operation.  Scaling Scale formations in boilers are responsible for lost efficiency, increased maintenance and operating costs not to mention lost revenue due to outages and downtime. Most scale formations in boilers occur due to the presence of hardness in the make-up water. This hardness reacts in the high temperatures environment within the boiler to form and insoluble scale. This insoluble scale coats the heat transfer surfaces, acting as an insulator to impede heat transfer. Hardness isn't the only cause of scale formation in boilers, other impurities such as iron, silica, copper, oil, etc. are often found in samples of boiler scale. In fact, it is rare to find scale which isn't the result of several of these impurities.  Slagging and Fouling Slagging occurs in boiler furnaces where ash deposits are exposed to the radiant heat of the coal flames, while fouling occurs in the boiler’s convective passes. Slagging & fouling are mainly observed in coal- fired boilers. Excessive ash deposits on a coal fired boiler’s heat transfer surfaces will reduce its efficiency, and in extreme cases a boiler can be shut down by ash related problems. It Slag on platen superheater tubes
  • 14. BOILERS Dec’ 2014 ENERGY ALTERNATIVES INDIA (EAI), CHENNAI www.eai.in Page 13 has been estimated that slagging incidents cost the global utility industry several billion dollars annually in reduced power generation and equipment maintenance.  Corrosion Corrosion occurs in boilers due to two major reasons. The most common cause is dissolved oxygen entering the system via the feed-water. Another common cause of corrosion in boiler systems is low pH within the boiler. This reduced pH may result from carbon dioxide infiltration or form contamination by other chemicals. The oxygen causes very localized corrosion to occur in the form of pitting. The pits are small but deep pinpoint holes which eventually can penetrate tube walls and cause their failure. Oxygen corrosion is normally controlled by driving the oxygen from the feed-water in a deaerating heater/deaerator or by chemically removing it with an oxygen scavenger such as sodium sulfite. There are many contaminates which can infiltrate a boiler system and cause low pH levels to develop.