Reboiler: Difference between revisions
imported>Milton Beychok m (Added a word) |
imported>Caesar Schinas m (Bot: Update image code) |
||
Line 1: | Line 1: | ||
{{subpages}} | {{subpages}} | ||
{{Image|Binary Distillation Column Schematic.png|right|210px|Figure 1: Schematic diagram of a continuous binary distillation column.}} | |||
A '''reboiler''' is typically a [[heat exchanger]] used to provide heat to the bottom of an industrial [[continuous distillation|distillation]] column (also referred to as a distillation ''tower'').<ref>{{cite book|author=Kister, Henry Z.|title= [[Distillation Design]]|edition=1st Edition |publisher=McGraw-Hill|year=1992|id=ISBN 0-07-034909-6}}</ref><ref>{{cite book|author=King, C.J.|2nd Edition|title=Separation Processes|publisher=McGraw Hill|year=1980|id=0-07-034612-7}}</ref><ref> | A '''reboiler''' is typically a [[heat exchanger]] used to provide heat to the bottom of an industrial [[continuous distillation|distillation]] column (also referred to as a distillation ''tower'').<ref>{{cite book|author=Kister, Henry Z.|title= [[Distillation Design]]|edition=1st Edition |publisher=McGraw-Hill|year=1992|id=ISBN 0-07-034909-6}}</ref><ref>{{cite book|author=King, C.J.|2nd Edition|title=Separation Processes|publisher=McGraw Hill|year=1980|id=0-07-034612-7}}</ref><ref> | ||
Line 14: | Line 14: | ||
Commonly used heat exchanger type reboilers are: | Commonly used heat exchanger type reboilers are: | ||
{{Image|Kettle reboiler.png|right|184px|Figure 2: A typical steam-heated kettle reboiler used for heating industrial distillation columns.}} | |||
===Kettle reboilers=== | ===Kettle reboilers=== | ||
Figure 2 depicts a typical steam-heated kettle reboiler used for heating industrial distillation columns. Kettle reboilers are very simple and reliable. They may require [[pump|pumping]] of the column bottoms liquid into the kettle, or there may be sufficient [[Head (fluid dynamics)|liquid head]] to deliver the liquid into the reboiler. In this reboiler type, steam flows through the tube bundle and exits as condensate (i.e., [[Condensation|condensed]] water). The liquid from the bottom of the tower, commonly called the ''bottoms'', flows through the shell side. There is a retaining wall or overflow ''weir'' separating the tube bundle from the reboiler section where the residual reboiled liquid (called the bottoms product) is withdrawn, so that the tube bundle is kept covered with liquid. | Figure 2 depicts a typical steam-heated kettle reboiler used for heating industrial distillation columns. Kettle reboilers are very simple and reliable. They may require [[pump|pumping]] of the column bottoms liquid into the kettle, or there may be sufficient [[Head (fluid dynamics)|liquid head]] to deliver the liquid into the reboiler. In this reboiler type, steam flows through the tube bundle and exits as condensate (i.e., [[Condensation|condensed]] water). The liquid from the bottom of the tower, commonly called the ''bottoms'', flows through the shell side. There is a retaining wall or overflow ''weir'' separating the tube bundle from the reboiler section where the residual reboiled liquid (called the bottoms product) is withdrawn, so that the tube bundle is kept covered with liquid. | ||
{{Image|Thermosyphon reboiler.png|right|315px|Figure 3: A typical steam-heated, horizontal thermosyphon reboiler used for heating distillation columns.}} | |||
===Thermosyphon reboilers === | ===Thermosyphon reboilers === | ||
Line 27: | Line 27: | ||
There are many types of thermosyphon reboilers. They may be vertical or horizontal and they may also be once-through or recirculating. Some fluids being reboiled may be temperature-sensitive and, for example, subject to [[polymerization]] by contact with high temperature heat transfer tube walls. In such cases, it is best to have a high liquid recirculation rate to avoid having high tube wall temperatures which would cause polymerization and, hence, fouling of the tubes. | There are many types of thermosyphon reboilers. They may be vertical or horizontal and they may also be once-through or recirculating. Some fluids being reboiled may be temperature-sensitive and, for example, subject to [[polymerization]] by contact with high temperature heat transfer tube walls. In such cases, it is best to have a high liquid recirculation rate to avoid having high tube wall temperatures which would cause polymerization and, hence, fouling of the tubes. | ||
{{Image|Fired Reboiler.png|right|350px|Figure 4: A typical forced recirculation fired heater reboiler used for heating a distillation column.}} | |||
===Fired reboiler=== | ===Fired reboiler=== | ||
Line 36: | Line 36: | ||
Typically, the heat source for a fired heater reboiler may be either fuel gas or fuel oil. Coal would rarely, if ever, be used as the fuel for a fired heater reboiler because the auxiliary equipment needed would make such a system very costly compared to using gas or oil as the fuel. | Typically, the heat source for a fired heater reboiler may be either fuel gas or fuel oil. Coal would rarely, if ever, be used as the fuel for a fired heater reboiler because the auxiliary equipment needed would make such a system very costly compared to using gas or oil as the fuel. | ||
{{Image|Forced Circulation Reboiler.png|right|350px|Figure 5: A typical steam-heated forced circulation exchanger used for heating a distillation column.}} | |||
===Forced circulation reboilers=== | ===Forced circulation reboilers=== |
Revision as of 08:48, 8 June 2009
A reboiler is typically a heat exchanger used to provide heat to the bottom of an industrial distillation column (also referred to as a distillation tower).[1][2][3] It boils the liquid from the bottom of a distillation column to generate vapors which are returned to the column to drive the distillation separation.
Proper reboiler operation is vital to effective distillation. In a typical continuous distillation column, all the heat required for the distillation is provide by a reboiler. Figure 1 is a schematic diagram of a typical industrial distillation column separating a mixture of liquid components into two products using the heat provided by a kettle-type reboiler.
Types of reboilers
The most critical element of reboiler design is the selection of the proper type of reboiler for a specific service. Most reboilers are of the shell and tube heat exchanger type and normally steam is used as the heat source in such reboilers. However, other heat transfer fluids like hot oil or Dowtherm (TM) may be used. Fuel-fired furnaces may also be used as reboilers in some cases.
Commonly used heat exchanger type reboilers are:
Kettle reboilers
Figure 2 depicts a typical steam-heated kettle reboiler used for heating industrial distillation columns. Kettle reboilers are very simple and reliable. They may require pumping of the column bottoms liquid into the kettle, or there may be sufficient liquid head to deliver the liquid into the reboiler. In this reboiler type, steam flows through the tube bundle and exits as condensate (i.e., condensed water). The liquid from the bottom of the tower, commonly called the bottoms, flows through the shell side. There is a retaining wall or overflow weir separating the tube bundle from the reboiler section where the residual reboiled liquid (called the bottoms product) is withdrawn, so that the tube bundle is kept covered with liquid.
Thermosyphon reboilers
Figure 3 is a schematic diagram of a steam-heated, horizontal thermosyphon reboiler. These do not require pumping of the column bottoms liquid into the reboiler. Natural circulation is obtained by using the density difference between the reboiler inlet column bottoms liquid and the reboiler outlet liquid-vapor mixture to provide sufficient liquid head to deliver the tower bottoms into the reboiler. Thermosyphon reboilers are more complex than kettle reboilers and require more attention from the plant operators.
There are many types of thermosyphon reboilers. They may be vertical or horizontal and they may also be once-through or recirculating. Some fluids being reboiled may be temperature-sensitive and, for example, subject to polymerization by contact with high temperature heat transfer tube walls. In such cases, it is best to have a high liquid recirculation rate to avoid having high tube wall temperatures which would cause polymerization and, hence, fouling of the tubes.
Fired reboiler
Fired heaters (furnaces) are sometimes used (for example, in the distilling of crude oil in petroleum refineries) as reboilers for the heating of large distillation columns. A pump is required to circulate the column bottoms through the heat transfer tubes in the furnace's convection and radiant sections.
Figure 4 is a schematic diagram of a fired heater being used in a configuration that provides recirculation of the column bottoms liquid. However, with some relatively minor changes inside the bottom section of the distillation column, a fired heater can also be used in once-through configuration.
Typically, the heat source for a fired heater reboiler may be either fuel gas or fuel oil. Coal would rarely, if ever, be used as the fuel for a fired heater reboiler because the auxiliary equipment needed would make such a system very costly compared to using gas or oil as the fuel.
Forced circulation reboilers
This type of reboiler uses a pump to circulate the column bottoms liquid through the reboilers. Figure 4 is a schematic diagram of a typical steam-heated forced circulation reboiler. Although Figure 4 depicts the steam flow as being one-pass through the exchanger, a two-pass flow system could also be used
It should be noted steam is not the only heat source that can be used. Any available process stream that is at a high enough temperature could be used for any of the many shell and tube heat exchanger reboiler types.
References
- ↑ Kister, Henry Z. (1992). Distillation Design, 1st Edition. McGraw-Hill. ISBN 0-07-034909-6.
- ↑ King, C.J. (1980). Separation Processes. McGraw Hill. 0-07-034612-7.
- ↑ Perry, Robert H. and Green, Don W. (2007). Perry's Chemical Engineers' Handbook, 8th Edition. McGraw-Hill. ISBN ISBN 0-07-142294-3.