Heatexchangers
rkp042
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Dec 11, 2014
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About This Presentation
to know about the heat exchangers,&there types,,as well as know about there propertys....
Slide Content
Heat Transfer Equipments
BY- RADHAKRISHAN PANDEY ROLL NO -67 BATCH - I
Objectives Recognize what is heat exchanger Differentiate numerous types of heat exchanger, their classification and their applications Know the heat transfer equipment terminologies Know the primary consideration in the selection of heat exchangers
What is a heat transfer equipment? An equipment that permits efficient transfer of heat from a hot fluid to a cold fluid without any or with direct contact of fluids Such an equipment is called Heat Exchanger
What is a Heat Exchanger ? Technically speaking …… A heat exchanger is a device that is used to transfer thermal energy (enthalpy) between two or more fluids , between a solid surface and a fluid , or between solid particulates and a fluid , at different temperatures and in thermal contact.
Heat Exchanger Heat exchangers, can be seen in daily life , like ?? as well as in industries, like??
Aim and Application of HE Typical applications involve heating or cooling of a fluid stream of concern and evaporation or condensation of single- or multicomponent fluid streams. In other applications, the objective may be to recover or reject heat, or sterilize, pasteurize, fractionate, distill, concentrate, crystallize, or control a process fluid . Common examples of heat exchangers are shell-and tube exchangers , automobile radiators, condensers, evaporators, air preheaters, and cooling towers.
Aim and Application of HE Heat exchanger found applications in almost all Chemical and petrochemical plants Air Conditioning Systems Power production Waste Heat recovery Automobile Radiator Central Heating System Electronic Parts
Different Terminologies of Heat Transfer Equipment Heat exchanger : both sides single-phase and process streams Cooler : one stream a process fluid and the other cooling water or air . Heater : one stream a process fluid and the other a hot utility, such as steam or hot oil . Condenser : one stream a condensing vapor and the other cooling water or air . Chiller : one stream a process fluid being condensed at sub-atmospheric temperatures and the other a boiling refrigerant or process stream . Reboiler : one stream a bottoms stream from a distillation column and the other a hot utility (steam or hot oil) or a process stream .
Heat Exchanger Classification Heat exchangers are classified according to Transfer process Number of fluids Degree of surface compactness Construction Flow arrangements Heat transfer mechanisms
Shah , 1981
Heat Exchanger Classification Heat exchangers are classified according to Transfer process
Classification by Transfer Processes
Classification by Transfer Processes Indirect contact type The fluid streams remain separate and the heat transfers continuously through a dividing wall into and out of the wall in a transient manner .
Classification by Transfer Processes Indirect contact type Direct transfer type heat exchanger Storage type heat exchanger Fluidized bed heat exchanger
Classification by Transfer Processes Direct Transfer Type Heat Exchanger In this, type heat transfers continuously from the hot fluid to the cold fluid through a dividing wall. There is no direct mixing of the fluids because each fluid flows in separate fluid passages. It is also known as recuperator . Examples, tubular exchangers, plate and frame heat exchangers and extended surface exchangers . Tubular Exchanger Plate and Frame Exchanger
Classification by Transfer Processes Storage Type Heat Exchanger (Regenerative Heat Exchanger) Fixed Bed Regenerator Continuous-passage matrices for a rotary regenerator: (a) notched plate ; ( b) triangular passage.
Classification by Transfer Processes Storage Type Heat Exchanger (Regenerative Heat Exchanger ) Regenerative heating was one of the most important technologies developed during the Industrial Revolution when it was used in the hot blast process on blast furnaces. It was later used in glass and steel making, to increase the efficiency of open hearth furnaces, and in high pressure boilers and chemical and other applications, where it continues to be important today.
Classification by Transfer Processes Fluidized bed heat exchanger In a fluidized-bed heat exchanger, one side of a two-fluid exchanger is immersed in a bed of finely divided solid material, such as a tube bundle immersed in a bed of sand or coal particles. The common applications of the fluidized-bed heat exchanger are drying, mixing, adsorption, reactor engineering, coal combustion, and waste heat recovery
Classification by Transfer Processes Direct-Contact Heat Exchanger In a direct-contact exchanger, two fluid streams come into direct contact, exchange heat, and are then separated. Common applications of a direct-contact exchanger involve mass transfer in addition to heat transfer, such as in evaporative cooling and rectification. However , the applications are limited to those cases where a direct contact of two fluid streams is permissible.
Classification by Transfer Processes Direct-Contact Heat Exchanger Immiscible Fluid Exchangers Gas–Liquid Exchangers Liquid–Vapor Exchangers
Classification by Transfer Processes Immiscible Fluid Exchangers In this type, two immiscible fluid streams are brought into direct contact. These fluids may be single-phase fluids, or they may involve condensation or vaporization. Condensation of organic vapors and oil vapors with water or air are typical examples.
Classification by Transfer Processes Gas–Liquid Exchangers In this type, one fluid is a gas (more commonly, air) and the other a low-pressure liquid (more commonly, water) and are readily separable after the energy exchange. In either cooling of liquid (water) or humidification of gas (air ) applications, liquid partially evaporates and the vapor is carried away with the gas. In these exchangers, more than 90% of the energy transfer is by virtue of mass transfer (due to the evaporation of the liquid), and convective heat transfer is a minor mechanism. A ‘‘wet’’ (water) cooling tower with forced- or natural-draft airflow is the most common application. Other applications are the air-conditioning spray chamber, spray drier, spray tower, and spray pond.
Classification by Transfer Processes Liquid–Vapor Exchangers In this type, typically steam is partially or fully condensed using cooling water, or water is heated with waste steam through direct contact in the exchanger. Noncondensables and residual steam and hot water are the outlet streams. Common examples are desuperheaters and open feedwater heaters ( also known as deaerators ) in power plants .
Classification by Transfer Processes Direct-Contact Heat Exchanger Compared to indirect contact recuperators and regenerators, in direct-contact heat exchangers, very high heat transfer rates are achievable, the exchanger construction is relatively inexpensive, and the fouling problem is generally nonexistent, due to the absence of a heat transfer surface (wall) between the two fluids.
Heat Exchanger Classification Heat exchangers are classified according to Number of fluids
Classification by Number of Fluid Most processes of heating, cooling, heat recovery, and heat rejection involve transfer of heat between two fluids. Hence , two-fluid heat exchangers are the most common. Three fluid heat exchangers are widely used in cryogenics and some chemical processes (e.g., air separation systems, a helium–air separation unit, purification and liquefaction of hydrogen, ammonia gas synthesis). Heat exchangers with as many as 12 fluid streams have been used in some chemical process applications.
Heat Exchanger Classification Heat exchangers are classified according to Degree of surface compactness
Classification by Surface Compactness β Heat exchangers are characterized by a large heat transfer surface area per unit volume of the exchanger, resulting in reduced space , reduce weight , reduce support structure and footprint, energy requirements and cost, as well as improved process design and plant layout and processing conditions, together with low fluid inventory.
Classification by Surface Compactness β The ratio of the heat transfer surface area of a heat exchanger to its volume is called the area density or surface compactness β . A heat exchanger with β = 700 m 2 /m 3 (or 200 ft 2 /ft 3 ) is classified as being compact. Examples of compact heat exchangers are car radiators ( 1000 m 2 /m 3 ) and the human lung ( 20,000 m 2 /m 3 ).
Heat Exchanger Classification Heat exchangers are classified according to Heat Transfer Mechanisms
Classification by Heat Transfer Mechanisms The basic heat transfer mechanisms employed for transfer of thermal energy from the fluid on one side of the exchanger to the wall (separating the fluid on the other side) are single-phase convection (forced or free), two-phase convection (condensation or evaporation , by forced or free convection), and combined convection and radiation heat transfer. Any of these mechanisms individually or in combination could be active on each fluid side of the exchanger . Some examples of each classification type are automotive radiators, passenger space heaters, regenerators, intercoolers, economizers and so on.
Heat Exchanger Classification Heat exchangers are classified according to Flow arrangements
Classification by Flow Arrangement
Classification by Flow Arrangement The choice of a particular flow arrangement is dependent on the required exchanger effectiveness , available pressure drops, minimum and maximum velocities allowed, fluid flow paths, packaging envelope, allowable thermal stresses, temperature levels, piping and plumbing considerations, and other design criteria.
Classification by Flow Arrangement Single Pass flow arrangement A fluid is considered to have made one pass if it flows through a section of the heat exchanger through its full length. Counterflow exchanger In a counterflow or countercurrent exchanger, the two fluids flow parallel to each other but in opposite directions within the core. The counterflow arrangement is thermodynamically superior to any other flow arrangement. It is the most efficient flow arrangement, producing the highest temperature change in each fluid compared to any other two-fluid flow arrangements for a given overall thermal conductance (UA), fluid flow rates and fluid inlet temperatures. The maximum temperature difference across the exchanger produces minimum thermal stresses in the wall for an equivalent performance compared to any other flow arrangements.
Classification by Flow Arrangement Single Pass flow arrangement Parallelflow exchanger In a parallelflow (also referred to as cocurrent or cocurrent parallel stream) exchanger, the fluid streams enter together at one end, flow parallel to each other in the same direction, and leave together at the other end . This arrangement has the lowest exchanger effectiveness among single-pass exchangers for given overall thermal conductance and fluid flow rates and fluid inlet temperatures. In a parallelflow exchanger, a large temperature difference between inlet temperatures of hot and cold fluids exists at the inlet side, which may induce high thermal stresses in the exchanger wall at the inlet.
Classification by Flow Arrangement Single Pass flow arrangement Crossflow Exchanger In this type of exchanger, the two fluids flow in directions normal to each other . Thermodynamically, the effectiveness for the crossflow exchanger falls in between that for the counterflow and parallel flow arrangements. The largest structural temperature difference exists at the ‘‘corner’’ of the entering hot and cold fluids. This is one of the most common flow arrangements used for extended surface heat exchangers, because it greatly simplifies the header design at the entrance and exit of each fluid.
Classification by Flow Arrangement Single Pass flow arrangement d) Splitflow Exchanger In this exchanger, the shell fluid stream enters at the center of the exchanger and divides into two streams. These streams flow in longitudinal directions along the exchanger length over a longitudinal baffle , make a 180° turn at each end, flow longitudinally to the center of the exchanger under the longitudinal baffle, unite at the center, and leave from the central nozzle . The other fluid stream flows straight in the tubes .
Classification by Flow Arrangement Multipass flow arrangement After flowing through one full length, if the flow direction is reversed and fluid flows through an equal- or different-sized section , it is considered to have made a second pass (or multipass ) of equal or different size .
Heat Exchanger Classification Heat exchangers are classified according to Construction
Classification by construction Tubular Double pipe Shell and tube Spiral tube Pipe coils Plate type Plate and frame Spiral Plate coil Printed circuit Extended surface Plate-fin Tube-fin Regenerative Rotary Fixed-matrix Rotating hoods
Shell and Tube HE
Double Pipe HE
Plate and Frame HE
Plate-Fin HE
Study Reference Materials Fundamentals of Heat Exchanger Design. Ramesh K. Shah and Dušan P. Sekulic , John Wiley & Sons, Inc . Heat Exchanger Design Handbook . Kuppan Thulukkanam , CRC Press .
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