Ambient condition effects on process heater efficiency

Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating conditions vary significantly from season to season and sometimes even within a given day. Unfortunately, most heaters are not properly adjust...

Full description

Saved in:
Bibliographic Details
Published inEnergy (Oxford) Vol. 34; no. 10; pp. 1624 - 1635
Main Authors Bussman, W.R., Baukal, C.E.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.10.2009
Elsevier
Subjects
Applied sciences
Crude oil, natural gas and petroleum products
Efficiency
Energy
Exact sciences and technology
Excess air
Excess O 2
Fuels
Humidity
Process heater
Processing of crude oil and oils from shales and tar sands. Processes. Equipment. Refinery and treatment units
Process heater
Excess air
Excess O 2
Efficiency
Humidity
Online AccessGet full text
ISSN0360-5442
DOI10.1016/j.energy.2009.07.009

Cover

Abstract Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating conditions vary significantly from season to season and sometimes even within a given day. Unfortunately, most heaters are not properly adjusted for actual operating conditions. Ambient air temperature, pressure and humidity all significantly impact process heater efficiency. This paper shows how changing ambient conditions can reduce efficiency if proper adjustments are not made. Combustion efficiency is related to air:fuel ratio and to air–fuel mixing. A general industry rule-of-thumb is that operating at 2–3% excess O 2 (dry basis) results in the best combination of efficiency and flexibility. At higher O 2 levels, efficiency is reduced because the additional O 2 and N 2 absorb heat, much of which exits the exhaust stack. At lower O 2 levels, efficiency can be substantially reduced because some fuel is uncombusted. Low O 2 levels can also lead to soot and coke buildup on process tubes reducing heat transfer to the process fluid and reducing efficiency. Several examples demonstrate how ambient conditions affect heater efficiency. Calculations and graphs for a wide range of operating conditions demonstrate how efficiency can be affected by changes in ambient conditions for process heaters.
AbstractList Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating conditions vary significantly from season to season and sometimes even within a given day. Unfortunately, most heaters are not properly adjusted for actual operating conditions. Ambient air temperature, pressure and humidity all significantly impact process heater efficiency. This paper shows how changing ambient conditions can reduce efficiency if proper adjustments are not made. Combustion efficiency is related to air:fuel ratio and to air-fuel mixing. A general industry rule-of-thumb is that operating at 2-3% excess O(2) (dry basis) results in the best combination of efficiency and flexibility. At higher O(2) levels, efficiency is reduced because the additional O(2) and N(2) absorb heat, much of which exits the exhaust stack. At lower O(2) levels, efficiency can be substantially reduced because some fuel is uncombusted. Low O(2) levels can also lead to soot and coke buildup on process tubes reducing heat transfer to the process fluid and reducing efficiency. Several examples demonstrate how ambient conditions affect heater efficiency. Calculations and graphs for a wide range of operating conditions demonstrate how efficiency can be affected by changes in ambient conditions for process heaters.
Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating conditions vary significantly from season to season and sometimes even within a given day. Unfortunately, most heaters are not properly adjusted for actual operating conditions. Ambient air temperature, pressure and humidity all significantly impact process heater efficiency. This paper shows how changing ambient conditions can reduce efficiency if proper adjustments are not made. Combustion efficiency is related to air:fuel ratio and to air–fuel mixing. A general industry rule-of-thumb is that operating at 2–3% excess O 2 (dry basis) results in the best combination of efficiency and flexibility. At higher O 2 levels, efficiency is reduced because the additional O 2 and N 2 absorb heat, much of which exits the exhaust stack. At lower O 2 levels, efficiency can be substantially reduced because some fuel is uncombusted. Low O 2 levels can also lead to soot and coke buildup on process tubes reducing heat transfer to the process fluid and reducing efficiency. Several examples demonstrate how ambient conditions affect heater efficiency. Calculations and graphs for a wide range of operating conditions demonstrate how efficiency can be affected by changes in ambient conditions for process heaters.
Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating conditions vary significantly from season to season and sometimes even within a given day. Unfortunately, most heaters are not properly adjusted for actual operating conditions. Ambient air temperature, pressure and humidity all significantly impact process heater efficiency. This paper shows how changing ambient conditions can reduce efficiency if proper adjustments are not made. Combustion efficiency is related to air:fuel ratio and to air-fuel mixing. A general industry rule-of-thumb is that operating at 2-3% excess O sub(2) (dry basis) results in the best combination of efficiency and flexibility. At higher O sub(2) levels, efficiency is reduced because the additional O sub(2) and N sub(2) absorb heat, much of which exits the exhaust stack. At lower O sub(2) levels, efficiency can be substantially reduced because some fuel is uncombusted. Low O sub(2) levels can also lead to soot and coke buildup on process tubes reducing heat transfer to the process fluid and reducing efficiency. Several examples demonstrate how ambient conditions affect heater efficiency. Calculations and graphs for a wide range of operating conditions demonstrate how efficiency can be affected by changes in ambient conditions for process heaters.
Author Baukal, C.E.
Bussman, W.R.
Author_xml – sequence: 1
  givenname: W.R.
  surname: Bussman
  fullname: Bussman, W.R.
  email: wes.bussman@johnzink.com
– sequence: 2
  givenname: C.E.
  surname: Baukal
  fullname: Baukal, C.E.
BackLink http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=22010649$$DView record in Pascal Francis
BookMark eNqFkb1OwzAYRT0UibbwBgxZYGv4bOfHYUCqKv6kSiwwW7bzGVylSbFTpL49DqkYGGC6lnzulXU8I5O2a5GQCwopBVpcb1Js0b8dUgZQpVCmMSZkCryARZ5l7JTMQtgAQC6qakqK5VY7bPvEdG3tete1CVqLpg9JPO58ZzCE5B1Vj364cSbS5nBGTqxqAp4fc05e7-9eVo-L9fPD02q5XhheiX5BFdBaC1YhpSxXttLU0MxyDRUrqNY808zkSgiLdQ5Cq5qXxmSi1KoAVTA-J1fjbnzJxx5DL7cuGGwa1WK3D5JHVhRZ9S_IKAiesyKCl0dQBaMa61VrXJA777bKHyRjQGEczEbO-C4Ej_YHoSAH03IjR9NyMC2hlDFi7eZXzbheDV57r1zzX_l2LGNU-unQy_CtG2vn45fIunN_D3wBPQuf_Q
CODEN ENEYDS
CitedBy_id crossref_primary_10_1002_htj_22358
crossref_primary_10_1016_j_conengprac_2016_07_004
crossref_primary_10_1007_s00158_016_1643_7
crossref_primary_10_1007_s10973_023_12065_9
crossref_primary_10_1016_j_energy_2011_02_056
Cites_doi 10.1016/j.energy.2004.03.021
10.1115/IMECE2008-68284
10.1016/j.energy.2006.08.008
10.1016/j.energy.2005.10.030
ContentType Journal Article
Copyright 2009 Elsevier Ltd
2015 INIST-CNRS
Copyright_xml – notice: 2009 Elsevier Ltd
– notice: 2015 INIST-CNRS
DBID AAYXX
CITATION
IQODW
7ST
C1K
SOI
7SP
7TB
8FD
F28
FR3
KR7
L7M
DOI 10.1016/j.energy.2009.07.009
DatabaseName CrossRef
Pascal-Francis
Environment Abstracts
Environmental Sciences and Pollution Management
Environment Abstracts
Electronics & Communications Abstracts
Mechanical & Transportation Engineering Abstracts
Technology Research Database
ANTE: Abstracts in New Technology & Engineering
Engineering Research Database
Civil Engineering Abstracts
Advanced Technologies Database with Aerospace
DatabaseTitle CrossRef
Environment Abstracts
Environmental Sciences and Pollution Management
Civil Engineering Abstracts
Technology Research Database
Mechanical & Transportation Engineering Abstracts
Electronics & Communications Abstracts
Engineering Research Database
Advanced Technologies Database with Aerospace
ANTE: Abstracts in New Technology & Engineering
DatabaseTitleList Civil Engineering Abstracts

Environment Abstracts
DeliveryMethod fulltext_linktorsrc
Discipline Economics
Environmental Sciences
Applied Sciences
EndPage 1635
ExternalDocumentID 22010649
10_1016_j_energy_2009_07_009
S0360544209002886
GroupedDBID --K
--M
.DC
.~1
0R~
1B1
1RT
1~.
1~5
29G
4.4
457
4G.
5GY
5VS
6TJ
7-5
71M
8P~
9JN
AABNK
AACTN
AAEDT
AAEDW
AAHCO
AAIAV
AAIKC
AAIKJ
AAKOC
AALRI
AAMNW
AAOAW
AAQFI
AAQXK
AARJD
AAXUO
ABFNM
ABJNI
ABMAC
ABXDB
ABYKQ
ACDAQ
ACGFS
ACIWK
ACRLP
ADBBV
ADEZE
ADMUD
AEBSH
AEKER
AENEX
AFKWA
AFRAH
AFTJW
AGHFR
AGUBO
AGYEJ
AHHHB
AHIDL
AIEXJ
AIKHN
AITUG
AJBFU
AJOXV
ALMA_UNASSIGNED_HOLDINGS
AMFUW
AMRAJ
ASPBG
AVWKF
AXJTR
AZFZN
BELTK
BKOJK
BLXMC
CS3
DU5
EBS
EFJIC
EFLBG
EJD
EO8
EO9
EP2
EP3
FDB
FEDTE
FGOYB
FIRID
FNPLU
FYGXN
G-2
G-Q
G8K
GBLVA
HVGLF
HZ~
IHE
J1W
JARJE
KOM
LY6
M41
MO0
N9A
O-L
O9-
OAUVE
OZT
P-8
P-9
P2P
PC.
Q38
R2-
RIG
RNS
ROL
RPZ
SAC
SDF
SDG
SES
SEW
SPC
SPCBC
SSR
SSZ
T5K
TN5
WUQ
XPP
ZMT
~02
~G-
AAHBH
AATTM
AAXKI
AAYWO
AAYXX
ABDPE
ABWVN
ACRPL
ACVFH
ADCNI
ADNMO
ADXHL
AEIPS
AEUPX
AFJKZ
AFPUW
AFXIZ
AGCQF
AGQPQ
AGRNS
AIGII
AIIUN
AKBMS
AKRWK
AKYEP
ANKPU
APXCP
BNPGV
CITATION
SSH
EFKBS
IQODW
7ST
C1K
SOI
7SP
7TB
8FD
F28
FR3
KR7
L7M
ID FETCH-LOGICAL-c398t-1a01db829e1125af9b1c14f3b09261bb34b2c5a88fed508bad37cc487ba60a623
IEDL.DBID .~1
ISSN 0360-5442
IngestDate Thu Sep 04 19:37:56 EDT 2025
Fri Sep 05 13:20:58 EDT 2025
Mon Jul 21 09:15:08 EDT 2025
Thu Apr 24 23:01:50 EDT 2025
Tue Jul 01 01:38:29 EDT 2025
Fri Feb 23 02:16:15 EST 2024
IsPeerReviewed true
IsScholarly true
Issue 10
Keywords Process heater
Excess air
Excess O 2
Efficiency
Humidity
Language English
License https://www.elsevier.com/tdm/userlicense/1.0
CC BY 4.0
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-c398t-1a01db829e1125af9b1c14f3b09261bb34b2c5a88fed508bad37cc487ba60a623
Notes ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
PQID 21083526
PQPubID 23462
PageCount 12
ParticipantIDs proquest_miscellaneous_34878649
proquest_miscellaneous_21083526
pascalfrancis_primary_22010649
crossref_primary_10_1016_j_energy_2009_07_009
crossref_citationtrail_10_1016_j_energy_2009_07_009
elsevier_sciencedirect_doi_10_1016_j_energy_2009_07_009
ProviderPackageCode CITATION
AAYXX
PublicationCentury 2000
PublicationDate 2009-10-01
PublicationDateYYYYMMDD 2009-10-01
PublicationDate_xml – month: 10
  year: 2009
  text: 2009-10-01
  day: 01
PublicationDecade 2000
PublicationPlace Kidlington
PublicationPlace_xml – name: Kidlington
PublicationTitle Energy (Oxford)
PublicationYear 2009
Publisher Elsevier Ltd
Elsevier
Publisher_xml – name: Elsevier Ltd
– name: Elsevier
References Faagau (bib1) 2008; 71
Vinayagam (bib32) 2007; 114
Worrell, Galitsky (bib18) 2005
IHEA (bib19) 1994
Reed (bib22) 1986; vol. I
Bussman W, Baukal C. Ambient condition effects on process heater emissions, proceedings of the International Mechanical Engineering Congress & Exhibition, paper IMECE2008-68284, Boston, MA, November 2008.
Gadalla, Olujić Ž, Smith (bib27) 2006; 31
American Petroleum Institute (bib15) February 2000
Szklo, Schaeffer (bib28) 2007; 32
Baukal (bib25) 2004
Energetics, Inc. (bib17) April 2004
(bib6) January 2006
Energetics, Inc. (bib2) November 2007
Worrell, Galitsky (bib14)
Petrick, Pellegrino (bib16) 1999
DiSimone (bib20) 2006; 11
Intergovernmental Panel on Climate Change. Climate change 2007: synthesis report.
Bussman W, Baukal C. Ambient condition effects on process heater emissions. Proceedings of the International Mechanical Engineering Congress & Exhibition, Paper IMECE2008-68284, Boston, MA, November 2008.
Energy Information Administration (bib10) 2002
ACME Refinery (bib13) June 28, 2000
Vinayagam (bib11) 2007; 86
(bib23) 2004
Barrieau (bib30) 1993; 47
(bib5) September 1995
U.S. Department of Energy – Energy and Renewable Energy (bib8) 2008
[Accessed 30.10.08].
(bib9) 1992
McQuiston, Parker (bib31) 1982
Chen, Yin, Wang, Hua (bib12) 2004; 29
Trinks, Mawhinney (bib4) 1961; vol. I
Key, Rupley, Miller (bib33) February 1992
Talmor (bib3) 1982
(bib7) 2001
Reed (bib21) 1981
(10.1016/j.energy.2009.07.009_bib9) 1992
Trinks (10.1016/j.energy.2009.07.009_bib4) 1961; vol. I
U.S. Department of Energy – Energy and Renewable Energy (10.1016/j.energy.2009.07.009_bib8) 2008
Talmor (10.1016/j.energy.2009.07.009_bib3) 1982
Key (10.1016/j.energy.2009.07.009_bib33) 1992
Gadalla (10.1016/j.energy.2009.07.009_bib27) 2006; 31
Reed (10.1016/j.energy.2009.07.009_bib21) 1981
McQuiston (10.1016/j.energy.2009.07.009_bib31) 1982
(10.1016/j.energy.2009.07.009_bib7) 2001
Szklo (10.1016/j.energy.2009.07.009_bib28) 2007; 32
Energetics, Inc. (10.1016/j.energy.2009.07.009_bib2) 2007
(10.1016/j.energy.2009.07.009_bib5) 1995
ACME Refinery (10.1016/j.energy.2009.07.009_bib13)
Chen (10.1016/j.energy.2009.07.009_bib12) 2004; 29
Petrick (10.1016/j.energy.2009.07.009_bib16) 1999
Vinayagam (10.1016/j.energy.2009.07.009_bib32) 2007; 114
Faagau (10.1016/j.energy.2009.07.009_bib1) 2008; 71
Energetics, Inc. (10.1016/j.energy.2009.07.009_bib17) 2004
IHEA (10.1016/j.energy.2009.07.009_bib19) 1994
10.1016/j.energy.2009.07.009_bib24
10.1016/j.energy.2009.07.009_bib26
Barrieau (10.1016/j.energy.2009.07.009_bib30) 1993; 47
Energy Information Administration (10.1016/j.energy.2009.07.009_bib10) 2002
Vinayagam (10.1016/j.energy.2009.07.009_bib11) 2007; 86
10.1016/j.energy.2009.07.009_bib29
(10.1016/j.energy.2009.07.009_bib6) 2006
American Petroleum Institute (10.1016/j.energy.2009.07.009_bib15) 2000
DiSimone (10.1016/j.energy.2009.07.009_bib20) 2006; 11
Baukal (10.1016/j.energy.2009.07.009_bib25) 2004
Worrell (10.1016/j.energy.2009.07.009_bib14)
Reed (10.1016/j.energy.2009.07.009_bib22) 1986; vol. I
Worrell (10.1016/j.energy.2009.07.009_bib18) 2005
(10.1016/j.energy.2009.07.009_bib23) 2004
References_xml – year: 1994
  ident: bib19
  article-title: Combustion technology manual
– volume: 29
  start-page: 2225
  year: 2004
  end-page: 2237
  ident: bib12
  article-title: Energy-use analysis and improvement for delayed coking units
  publication-title: Energy
– volume: 32
  start-page: 1075
  year: 2007
  end-page: 1092
  ident: bib28
  article-title: Fuel specification, energy consumption and CO
  publication-title: Energy
– volume: 11
  start-page: 103
  year: 2006
  end-page: 111
  ident: bib20
  article-title: Furnace combustion management
  publication-title: Petroleum Technology Quarterly
– volume: 86
  start-page: 95
  year: 2007
  end-page: 104
  ident: bib11
  article-title: Understanding the secrets of fired heaters tuning
  publication-title: Hydrocarbon Processing
– volume: 71
  start-page: 16
  year: 2008
  ident: bib1
  article-title: Resolve to trim that excess air
  publication-title: Chemical Processing
– year: February 2000
  ident: bib15
  article-title: Technology roadmap for the petroleum industry
– year: 2005
  ident: bib18
  article-title: Energy efficiency improvement and cost saving opportunities for petroleum refineries
  publication-title: Lawrence Berkeley National Laboratory report LBNL-56183
– year: June 28, 2000
  ident: bib13
  article-title: Process heater efficiency testing results and annual cost saving calculations
– volume: vol. I
  year: 1986
  ident: bib22
  article-title: Combustion, fuels, stoichiometry, heat transfer, fluid low
  publication-title: The North American combustion handbook
– ident: bib14
  article-title: Profile of the petroleum refining industry in California
– year: 1982
  ident: bib3
  article-title: Combustion hot spot analysis for fired process heaters
– year: February 1992
  ident: bib33
  article-title: The Chemkin thermodynamic data base
– year: 2001
  ident: bib7
  publication-title: The John Zink combustion handbook
– year: 1981
  ident: bib21
  article-title: Furnace operations
– reference: . [Accessed 30.10.08].
– volume: 31
  start-page: 2398
  year: 2006
  end-page: 2408
  ident: bib27
  article-title: Estimation and reduction of CO
  publication-title: Energy
– year: 2008
  ident: bib8
  article-title: Industrial Technologies Program, NAICS 334110 petroleum refining energy footprint
– year: 2004
  ident: bib23
  publication-title: Industrial burners handbook
– year: January 2006
  ident: bib6
  article-title: American Petroleum Institute Recommended Practice 535. Burners for fired heaters in general refinery services
– year: 2004
  ident: bib25
  article-title: Industrial combustion pollution and control
– volume: 114
  start-page: 70
  year: 2007
  end-page: 73
  ident: bib32
  article-title: Minimizing flame impingements in fired heaters
  publication-title: Chemical Engineering
– volume: vol. I
  year: 1961
  ident: bib4
  publication-title: Industrial furnaces
– year: September 1995
  ident: bib5
  article-title: American Petroleum Institute Standard 560. Fired heaters for general refinery services
– year: 2002
  ident: bib10
  article-title: Manufacturing Energy Consumption Survey (MECS)
– volume: 47
  start-page: 86
  year: 1993
  end-page: 90
  ident: bib30
  article-title: Preventing common problems in boilers
  publication-title: Plant Engineering
– year: 1992
  ident: bib9
  publication-title: Combustion engineering and gas utilisation (sic)
– reference: Bussman W, Baukal C. Ambient condition effects on process heater emissions, proceedings of the International Mechanical Engineering Congress & Exhibition, paper IMECE2008-68284, Boston, MA, November 2008.
– year: April 2004
  ident: bib17
  article-title: Energy efficiency roadmap for petroleum refineries in California
  publication-title: Report prepared for the California Energy Commission under contract 500-03-010
– reference: Bussman W, Baukal C. Ambient condition effects on process heater emissions. Proceedings of the International Mechanical Engineering Congress & Exhibition, Paper IMECE2008-68284, Boston, MA, November 2008.
– year: 1982
  ident: bib31
  article-title: Heating, ventilating, and air conditioning
– year: 1999
  ident: bib16
  article-title: The potential for reducing energy utilization in the refining industry
  publication-title: Argonne National Laboratory report ANL/ESD/TM-158
– year: November 2007
  ident: bib2
  article-title: Energy and environmental profile of the U.S. petroleum refining industry
– reference: Intergovernmental Panel on Climate Change. Climate change 2007: synthesis report.
– year: 1982
  ident: 10.1016/j.energy.2009.07.009_bib3
– volume: 11
  start-page: 103
  issue: 4
  year: 2006
  ident: 10.1016/j.energy.2009.07.009_bib20
  article-title: Furnace combustion management
  publication-title: Petroleum Technology Quarterly
– volume: 29
  start-page: 2225
  year: 2004
  ident: 10.1016/j.energy.2009.07.009_bib12
  article-title: Energy-use analysis and improvement for delayed coking units
  publication-title: Energy
  doi: 10.1016/j.energy.2004.03.021
– ident: 10.1016/j.energy.2009.07.009_bib14
– year: 1992
  ident: 10.1016/j.energy.2009.07.009_bib9
– volume: vol. I
  year: 1986
  ident: 10.1016/j.energy.2009.07.009_bib22
  article-title: Combustion, fuels, stoichiometry, heat transfer, fluid low
– volume: 86
  start-page: 95
  issue: 10
  year: 2007
  ident: 10.1016/j.energy.2009.07.009_bib11
  article-title: Understanding the secrets of fired heaters tuning
  publication-title: Hydrocarbon Processing
– year: 1992
  ident: 10.1016/j.energy.2009.07.009_bib33
– year: 1981
  ident: 10.1016/j.energy.2009.07.009_bib21
– year: 2006
  ident: 10.1016/j.energy.2009.07.009_bib6
– ident: 10.1016/j.energy.2009.07.009_bib26
  doi: 10.1115/IMECE2008-68284
– year: 2000
  ident: 10.1016/j.energy.2009.07.009_bib15
– year: 1999
  ident: 10.1016/j.energy.2009.07.009_bib16
  article-title: The potential for reducing energy utilization in the refining industry
– ident: 10.1016/j.energy.2009.07.009_bib24
  doi: 10.1115/IMECE2008-68284
– volume: 71
  start-page: 16
  issue: 1
  year: 2008
  ident: 10.1016/j.energy.2009.07.009_bib1
  article-title: Resolve to trim that excess air
  publication-title: Chemical Processing
– year: 2007
  ident: 10.1016/j.energy.2009.07.009_bib2
– year: 2001
  ident: 10.1016/j.energy.2009.07.009_bib7
– ident: 10.1016/j.energy.2009.07.009_bib13
– volume: 32
  start-page: 1075
  year: 2007
  ident: 10.1016/j.energy.2009.07.009_bib28
  article-title: Fuel specification, energy consumption and CO2 emission in oil refineries
  publication-title: Energy
  doi: 10.1016/j.energy.2006.08.008
– year: 2008
  ident: 10.1016/j.energy.2009.07.009_bib8
– year: 2004
  ident: 10.1016/j.energy.2009.07.009_bib23
– volume: 47
  start-page: 86
  issue: 19
  year: 1993
  ident: 10.1016/j.energy.2009.07.009_bib30
  article-title: Preventing common problems in boilers
  publication-title: Plant Engineering
– volume: 31
  start-page: 2398
  year: 2006
  ident: 10.1016/j.energy.2009.07.009_bib27
  article-title: Estimation and reduction of CO2 emissions from crude oil distillation units
  publication-title: Energy
  doi: 10.1016/j.energy.2005.10.030
– year: 1982
  ident: 10.1016/j.energy.2009.07.009_bib31
– volume: vol. I
  year: 1961
  ident: 10.1016/j.energy.2009.07.009_bib4
– year: 1995
  ident: 10.1016/j.energy.2009.07.009_bib5
– year: 2002
  ident: 10.1016/j.energy.2009.07.009_bib10
– year: 2005
  ident: 10.1016/j.energy.2009.07.009_bib18
  article-title: Energy efficiency improvement and cost saving opportunities for petroleum refineries
– volume: 114
  start-page: 70
  issue: 5
  year: 2007
  ident: 10.1016/j.energy.2009.07.009_bib32
  article-title: Minimizing flame impingements in fired heaters
  publication-title: Chemical Engineering
– ident: 10.1016/j.energy.2009.07.009_bib29
– year: 2004
  ident: 10.1016/j.energy.2009.07.009_bib17
  article-title: Energy efficiency roadmap for petroleum refineries in California
– year: 1994
  ident: 10.1016/j.energy.2009.07.009_bib19
– year: 2004
  ident: 10.1016/j.energy.2009.07.009_bib25
SSID ssj0005899
Score 1.9720052
Snippet Process heaters are typically located outside and subject to the weather. Although heaters are typically tuned at a given set of conditions, actual operating...
SourceID proquest
pascalfrancis
crossref
elsevier
SourceType Aggregation Database
Index Database
Enrichment Source
Publisher
StartPage 1624
SubjectTerms Applied sciences
Crude oil, natural gas and petroleum products
Efficiency
Energy
Exact sciences and technology
Excess air
Excess O 2
Fuels
Humidity
Process heater
Processing of crude oil and oils from shales and tar sands. Processes. Equipment. Refinery and treatment units
Title Ambient condition effects on process heater efficiency
URI https://dx.doi.org/10.1016/j.energy.2009.07.009
https://www.proquest.com/docview/21083526
https://www.proquest.com/docview/34878649
Volume 34
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1LS8QwEA6iBwURn_hce_Aat23SNDkuoqwuevCB3kpehRVdF3c9ePG3O5OmPhARPLW0ExomyfQb5psZQg5YZkypZUYBfaeUK-eotEVBtTBMlNwJZTGie34h-jf87K64myFHbS4M0iqj7W9serDW8Uk3arM7Hg67V2B7AW_wPFXoOEgsu815ifXzD9--0Dxk6CGJwhSl2_S5wPHyIb8uVq3EWobqt9_T4lhPQGl10-3ih-EOf6OTZbIUYWTSa2a6Qmb8aJXMt1nGk1WycfyZwQaC8QhP1ojoPRrMgUxA1gW-VhI5HQncjpu8gQRNtH_GN8Mw8nWd3JwcXx_1aWyeQC1TckoznWbOyFx5QFSFrpXJbMZrZlIFTpMxjJvcFlrK2jsAaUY7VloL7ovRItUAijbI7Ohp5DdJUsq05t5KAC9w5K1TLAPckntdC1jL1G0R1uqssrGyODa4eKhaCtl91Wgam16qKsWQt9oi9GPUuKms8Yd82S5H9W2HVGD8_xjZ-bZ6H5_LkQogOAjst8tZwenCkIke-aeXSQUOMUJU8bsEA5WBZtT2v6e3QxZCiCowBHfJ7PT5xe8B0pmaTtjKHTLXOx30L_A6uLwdvAMGDf-w
linkProvider Elsevier
linkToHtml http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1LTxsxEB5ROFCpqspLBGiyB64mu2uv1z5GKChtAxdA4mb5tVJQSSISDr30t3fs9dIihJB6W-2OtdaMPf6s-WYG4JQWxtRaFATRd06YdI4IW1VEc0N5zRyXNkR0L6_45JZ9v6vuNuC8y4UJtMrk-1ufHr11ejNM2hwuZ7PhNfpexBuszGW4OAj-AbZYReuwtM9-_8PzELGJZJAmQbzLn4skLx8T7FLZylDMUL51Pn1a6hVqrWnbXbzy3PE4uvgCnxOOzEbtVHdgw893YbtLM17twsH4bwobCqY9vNoDPnowIQkyQ1kXCVtZInVk-LhsEwey4KP9Y_gyiyN_7cPtxfjmfEJS9wRiqRRrUui8cEaU0iOkqnQjTWEL1lCTS7w1GUOZKW2lhWi8Q5RmtKO1tXh_MZrnGlHRAWzOF3N_CFkt8oZ5KxC94J63TtICgUvpdcPRmLnrAe10pmwqLR46XPxUHYfsXrWaDl0vpcpDzFv2gDyPWralNd6RrztzqBdLRKH3f2dk_4X1nn9XBi4AZygw6MypcHuFmIme-8XTSuGNOGBU_rYERZWhZuTRf09vANuTm8upmn67-nEMH2O8KtIFT2Bz_fjkvyLsWZt-XNZ_AOei_6M
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Ambient+condition+effects+on+process+heater+efficiency&rft.jtitle=Energy+%28Oxford%29&rft.au=Bussman%2C+W+R&rft.au=Baukal%2C+CE&rft.date=2009-10-01&rft.issn=0360-5442&rft.volume=34&rft.issue=10&rft.spage=1624&rft.epage=1635&rft_id=info:doi/10.1016%2Fj.energy.2009.07.009&rft.externalDBID=NO_FULL_TEXT
thumbnail_l http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=0360-5442&client=summon
thumbnail_m http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=0360-5442&client=summon
thumbnail_s http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=0360-5442&client=summon