�ݺ�ߣshows by User: AnupPaulElias

�ݺ�ߣshows by User: AnupPaulElias / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: AnupPaulElias / Wed, 06 Jun 2018 16:07:54 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: AnupPaulElias Divide your distillation column with confidence /slideshow/divide-your-distillation-column-with-confidence-100958615/100958615 divideyourdistillationcolumnwithconfidence-180606160754
Distillation is the primary separation process used in the chemical processing industries which approximately consume 40% to 50% of total energy use in the industry. Significant savings in both energy and capital costs can be achieved using Dividing Wall Distillation Column (DWC) compared to the conventional distillation column. DWC can significantly reduce capital and energy expense compared to conventional distillation towers by approximately 30-40% however, implementation of DWC concept is not the optimal solution for every fractionation and each application must be thoroughly reviewed if DWC can bring desirable benefits. This paper elaborates the benefits in terms of capital and energy consumption by reducing additional conventional column and cooling and heating utilities. There are number of tools used in such analysis, including process simulation package, mass transfer equipment hydraulic rating, capital cost estimation, etc. This paper also gives the major highlights on process parameters that need to be considered during modeling of DWC, like column size, metallurgy, operating pressure, pressure balance, etc. as well as important parameters that need to be inspected during column internals installation.]]>
Distillation is the primary separation process used in the chemical processing industries which approximately consume 40% to 50% of total energy use in the industry. Significant savings in both energy and capital costs can be achieved using Dividing Wall Distillation Column (DWC) compared to the conventional distillation column. DWC can significantly reduce capital and energy expense compared to conventional distillation towers by approximately 30-40% however, implementation of DWC concept is not the optimal solution for every fractionation and each application must be thoroughly reviewed if DWC can bring desirable benefits. This paper elaborates the benefits in terms of capital and energy consumption by reducing additional conventional column and cooling and heating utilities. There are number of tools used in such analysis, including process simulation package, mass transfer equipment hydraulic rating, capital cost estimation, etc. This paper also gives the major highlights on process parameters that need to be considered during modeling of DWC, like column size, metallurgy, operating pressure, pressure balance, etc. as well as important parameters that need to be inspected during column internals installation.]]> Wed, 06 Jun 2018 16:07:54 GMT /slideshow/divide-your-distillation-column-with-confidence-100958615/100958615 AnupPaulElias@slideshare.net(AnupPaulElias) Divide your distillation column with confidence AnupPaulElias Distillation is the primary separation process used in the chemical processing industries which approximately consume 40% to 50% of total energy use in the industry. Significant savings in both energy and capital costs can be achieved using Dividing Wall Distillation Column (DWC) compared to the conventional distillation column. DWC can significantly reduce capital and energy expense compared to conventional distillation towers by approximately 30-40% however, implementation of DWC concept is not the optimal solution for every fractionation and each application must be thoroughly reviewed if DWC can bring desirable benefits. This paper elaborates the benefits in terms of capital and energy consumption by reducing additional conventional column and cooling and heating utilities. There are number of tools used in such analysis, including process simulation package, mass transfer equipment hydraulic rating, capital cost estimation, etc. This paper also gives the major highlights on process parameters that need to be considered during modeling of DWC, like column size, metallurgy, operating pressure, pressure balance, etc. as well as important parameters that need to be inspected during column internals installation. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/divideyourdistillationcolumnwithconfidence-180606160754-thumbnail.jpg?width=120&height=120&fit=bounds" /><br> Distillation is the primary separation process used in the chemical processing industries which approximately consume 40% to 50% of total energy use in the industry. Significant savings in both energy and capital costs can be achieved using Dividing Wall Distillation Column (DWC) compared to the conventional distillation column. DWC can significantly reduce capital and energy expense compared to conventional distillation towers by approximately 30-40% however, implementation of DWC concept is not the optimal solution for every fractionation and each application must be thoroughly reviewed if DWC can bring desirable benefits. This paper elaborates the benefits in terms of capital and energy consumption by reducing additional conventional column and cooling and heating utilities. There are number of tools used in such analysis, including process simulation package, mass transfer equipment hydraulic rating, capital cost estimation, etc. This paper also gives the major highlights on process parameters that need to be considered during modeling of DWC, like column size, metallurgy, operating pressure, pressure balance, etc. as well as important parameters that need to be inspected during column internals installation.

Divide your distillation column with confidence from Anup E

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