This document provides guidelines for cooling tower design, including key parameters to consider. It discusses heat load calculation, circulating water rate, wet bulb temperatures, optimizing costs, makeup water, blowdown rates, and cycles of concentration. Electrical installations for cooling towers must use corrosion-resistant materials and hazardous area classifications due to possible flammable gas releases. Environmental and safety concerns like effluent quality and fire protection are also addressed.
This document provides best practices for loading catalyst into steam reformer tubes. It discusses using socks to uniformly distribute catalyst at a controlled rate of 3 feet or less of freefall. Pressure drop should be measured across tubes to ensure uniform packing. Common problems like bridging or uneven settling can be addressed through vibration or repacking. Precise loading techniques help minimize issues like temperature variations or methane slip that reduce efficiency and tube life.
Design Calculation of Venting for Atmospheric & Low Pressure Storage TanksKushagra Saxena
Storage Tanks are a very important part of a petroleum Industry, This software is based on the API Std. 2000, which calculates the design of Venting and its capacity for low pressure storage & atmospheric storage tanks in case of normal venting, due to thermal changes, and in case of fire exposure.
If you are in need of this software, Kindly contact at saxena.95kushagra@gmail.com
Pressure relieving valves like safety valves and safety relief valves are used in thermal power plants to prevent overpressure in pressurized systems. There are different types including safety valves, safety relief valves, and power operated relief valves. Safety valves open fully at a set pressure while safety relief valves can open proportionally. Standards like ASME Section I provide requirements for safety valve installation, capacity, materials, and settings to ensure systems are properly protected from overpressure. Safety valves are part of defense-in-depth protection schemes used in power plants to prevent accidents.
VARIOUS METHODS OF CENTRIFUGAL COMPRESSOR SURGE CONTROLVijay Sarathy
This document discusses four methods of surge control for centrifugal compressors: 1) controlling surge with a simple minimum flow cold bypass between the discharge and suction sides; 2) controlling surge by altering compressor speed to meet discharge pressure requirements; 3) controlling surge by altering inlet guide vanes or compressor speed to reset cold bypass flow; 4) controlling surge by correlating differential pressure across the compressor to reset minimum cold bypass flow.
The document discusses a student project on thermal power plants. It includes:
1) An introduction of the students and professor overseeing the project.
2) The objectives of the project which are to study how power is generated in thermal plants, the components like boilers and causes of boiler tube failures.
3) An outline of topics to be covered like the power generation principle, boilers, failures and case studies.
The document provides an overview of a module on flare system design and calculation. It discusses gas flaring definitions, components of a flare system, types of flares, environmental impacts, and considerations for flare system design and sizing calculations. Key aspects covered include gas flaring principles, when flaring occurs, composition of flared gases, reducing flaring through recovery systems, and sizing the flare header to minimize backpressure while limiting gas velocity.
The document summarizes the basics of pressure relief devices, including why they are required, common components, classification and types. It provides examples of relief scenarios and causes of overpressure. The key steps in relief device sizing calculations are outlined. An example calculation is shown for checking the adequacy of installed relief devices for a reactor system during an emergency relief scenario involving an external fire.
This document provides best practices for loading catalyst into steam reformer tubes. It discusses using socks to uniformly distribute catalyst at a controlled rate of 3 feet or less of freefall. Pressure drop should be measured across tubes to ensure uniform packing. Common problems like bridging or uneven settling can be addressed through vibration or repacking. Precise loading techniques help minimize issues like temperature variations or methane slip that reduce efficiency and tube life.
Design Calculation of Venting for Atmospheric & Low Pressure Storage TanksKushagra Saxena
Storage Tanks are a very important part of a petroleum Industry, This software is based on the API Std. 2000, which calculates the design of Venting and its capacity for low pressure storage & atmospheric storage tanks in case of normal venting, due to thermal changes, and in case of fire exposure.
If you are in need of this software, Kindly contact at saxena.95kushagra@gmail.com
Pressure relieving valves like safety valves and safety relief valves are used in thermal power plants to prevent overpressure in pressurized systems. There are different types including safety valves, safety relief valves, and power operated relief valves. Safety valves open fully at a set pressure while safety relief valves can open proportionally. Standards like ASME Section I provide requirements for safety valve installation, capacity, materials, and settings to ensure systems are properly protected from overpressure. Safety valves are part of defense-in-depth protection schemes used in power plants to prevent accidents.
VARIOUS METHODS OF CENTRIFUGAL COMPRESSOR SURGE CONTROLVijay Sarathy
This document discusses four methods of surge control for centrifugal compressors: 1) controlling surge with a simple minimum flow cold bypass between the discharge and suction sides; 2) controlling surge by altering compressor speed to meet discharge pressure requirements; 3) controlling surge by altering inlet guide vanes or compressor speed to reset cold bypass flow; 4) controlling surge by correlating differential pressure across the compressor to reset minimum cold bypass flow.
The document discusses a student project on thermal power plants. It includes:
1) An introduction of the students and professor overseeing the project.
2) The objectives of the project which are to study how power is generated in thermal plants, the components like boilers and causes of boiler tube failures.
3) An outline of topics to be covered like the power generation principle, boilers, failures and case studies.
The document provides an overview of a module on flare system design and calculation. It discusses gas flaring definitions, components of a flare system, types of flares, environmental impacts, and considerations for flare system design and sizing calculations. Key aspects covered include gas flaring principles, when flaring occurs, composition of flared gases, reducing flaring through recovery systems, and sizing the flare header to minimize backpressure while limiting gas velocity.
The document summarizes the basics of pressure relief devices, including why they are required, common components, classification and types. It provides examples of relief scenarios and causes of overpressure. The key steps in relief device sizing calculations are outlined. An example calculation is shown for checking the adequacy of installed relief devices for a reactor system during an emergency relief scenario involving an external fire.
Thermax Limited provides consulting services for efficient steam systems, including piping design, equipment selection, and design of condensate recovery and waste heat recovery systems. They offer utilities audits to analyze steam, compressed air, cooling, and power systems with the goal of optimizing costs. Their expertise includes selection and sizing of equipment such as pressure reducing stations, traps, and insulation. High-pressure condensate recovery systems can provide fuel savings of 15-20% by recovering heat from flash steam and condensate.
1. The document discusses procedures for calculating pressure safety valve (PSV) sizes for various scenarios that could lead to overpressure. It covers scenarios like closed outlets, external fires, control valve failures, hydraulic expansion, heat exchanger tube ruptures, and power or cooling failures.
2. Calculation methods include enthalpy balances for fractionating columns and the use of relief equations specified in codes like API 521. Worst cases are chosen from all possible scenarios to determine the required PSV size.
3. Key scenarios discussed in detail include closed outlets on vessels, external fires, failures of automatic controls, hydraulic expansion, heat exchanger tube ruptures, total and partial power failures, reflux losses,
Safety is the most important factor in designing a process system. Some undesired conditions might happen leading to damage in a system. Control systems might be installed to prevent such conditions, but a second safety device is also needed. One kind of safety device which is commonly used in the processing industry is the relief valve. A relief valve is a type of valve to control or limit the pressure in a system by allowing the pressurised fluid to flow out from the system.
This document provides an overview of using HTRI software to perform thermal design of heat exchangers. It discusses specifying the geometry, process conditions, and fluid properties required for rating, designing, or simulating shell and tube heat exchangers. Key aspects covered include baffle types, temperature profiles, mean temperature differences, and outputs such as duty, heat transfer area, and pressure drop. The goal is to demonstrate the inputs and calculations used in HTRI to analyze heat exchanger performance.
This document summarizes API STD 521 Part-I, which provides guidance on overpressure protection for refinery equipment. It discusses overpressure causes and protection philosophies. It also lists the minimum recommended contents for relief system designs and flare header calculations. These include analyzing overpressure causes, operating conditions, relief device sizing, and documentation of simulation inputs and outputs. Various overpressure causes are outlined, such as closed outlets, absorbent or cooling failures, accumulation of non-condensables, abnormal heat input, explosions, and depressurizing. Protection measures against these causes like relief valves, rupture disks, and explosion prevention are also mentioned.
The document describes the modified Claus process for sulfur recovery. It discusses the basic Claus reaction and how the modified process improved on it with a free flame oxidation ahead of the catalyst bed and catalytic step revisions, allowing for higher sulfur recovery efficiencies of 90-99.9%. The key steps of the modified Claus process are presented as the combustion step and multiple catalytic steps. Process variations like the straight-through and split-flow configurations are described along with tail gas handling and other sulfur removal processes. Sample calculations are provided to determine the optimum operating parameters for a 80 long ton per day sulfur recovery unit using the modified Claus process.
Alfa Laval owns the global trademarks for MISSIONTM and Alfa Laval. The document discusses Alfa Laval's thermal fluid heating systems, which use circulating oil to transfer heat from fuel-fired heaters to applications like fuel and cargo tanks. Alfa Laval is a global leader in supplying complete thermal fluid systems and has over 30 years of experience in the technology. Their systems offer advantages like high temperature capability, low maintenance, and global after-sales support.
Fired heaters are used to provide heat through the combustion of fuel. They involve combustion fundamentals like the reaction of methane and oxygen. Fired heaters have a furnace design and use draft systems and air preheaters. They employ different types of burners like those used in hot oil heaters and regeneration gas heaters. The start-up process involves inspection, purging, lighting pilots and burners, and adjusting temperatures and flows. Operation requires monitoring air adjustment, temperatures, and addressing potential issues like deposits, failures, or flame-outs. Control strategies manage variables like temperatures, fuels, and flows.
This document provides an overview and summary of a basic training course on petroleum storage tanks. It discusses various tank types including fixed roof tanks, internal floating roof tanks, and floating roof tanks. It covers tank design elements like the structure of the tank bottom and floor, thickness of bottom plates, and attachment of the bottom to the shell. It also addresses tank foundations, including the need for foundations to allow for leak detection. The goals of the training are identified as learning to identify tank types and equipment, understand tank limitations, perform volume calculations, and operate tanks safely.
Air Cooled Heat Exchanger Design
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 SUITABILITY FOR AIR COOLING
4.1 Options Available For Cooling
4.2 Choice of Cooling System
5 SPECIFICATION OF AN AIR COOLED HEAT
EXCHANGER
5.1 Description and Terminology
5.2 General
5.3 Thermal Duty and Design Margins
5.4 Process Pressure Drop
5.5 Design Ambient Conditions
5.6 Process Physical Properties
5.7 Mechanical Design Constraints
5.8 Arrangement
5.9 Air Side Fouling
5.10 Economic Factors in Design
6 CONTROL
7 PRESSURE RELIEF
8 ASSESSMENT OF OFFERS
8.1 General
8.2 Manual Checking Of Designs
8.3 Computer Assessment
8.4 Bid Comparison
9 FOULING AND CORROSION
9.1 Fouling
9.2 Corrosion
10 OPERATION AND MAINTENANCE
10.1 Performance Testing
10.2 Air-Side Cleaning
10.3 Mechanical Maintenance
10.4 Tube side Access
11 REFERENCES
Heaters are used in refineries to raise the temperature of process fluids. There are different types of heaters classified by design and firing method. Key components include tubes, burners, and sections for convection and radiation. Proper draft, excess air, and complete combustion are important for safe and efficient operation. Regular checks help ensure heaters are functioning properly and identify any issues.
This document provides information on fired heaters, including methods of heat transfer, combustion, types of fired heaters, furnace parts, problems that can occur, and introduces several heaters at a refinery. It discusses the three main methods of heat transfer as conduction, convection, and radiation. Fired heaters use combustion of fuel to generate heat that is transferred to process fluids through tubes. Box and cylindrical designs are described. Key furnace parts and issues like overfiring, vibration, and inefficiency are outlined. Example heaters at the refinery include crude, vacuum, visbreaker, and hydrotreating unit heaters.
Thermal Design Margins for Heat Exchangers
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 TERMINOLOGY
5 REASONS FOR SPECIFYING A DESIGN MARGIN
5.1 Instantaneous Rates
5.2 Future Uprating
5.3 Plant Upsets
5.4 Process Control
5.5 Uncertainties in Properties
5.6 Uncertainties in Design Methods
5.7 Fouling
6 COMBINATION OF DESIGN MARGINS
7 CRITICAL AND NON-CRITICAL DUTIES
7.1 General
7.2 Penalties of Over-design
8 OPTIMIZATION OF EXCHANGER DUTY
9 WAYS OF PROVIDING DESIGN MARGINS
9.1 The Provision of Excess Surface
9.2 Decreasing the Design Temperature Difference
9.3 Increasing the Design Process Throughput
9.4 Increasing the Design Fouling Resistance
9.5 Reducing the Design Process Outlet Temperature Approach
9.6 Adjusting the Physical Properties
10 ACCURACY OF THE DESIGN METHODS FOR SHELL AND TUBE EXCHANGERS
10.1 Pressure Drop
10.2 Heat Transfer
11 SUGGESTED DESIGN MARGINS
11.1 No Phase Change Duties
11.2 Condensers
11.3 Boilers
12 EFFECT OF UNDER- OR OVER-SURFACE ON PERFORMANCE
FIGURES
1 EFFECT OF LENGTH ON EXCHANGER DUTY COUNTERCURRENT FLOW, C* = 1.0
2 EFFECT OF NUMBER OF TUBES ON EXCHANGER PERFORMANCE COUNTERCURRENT FLOW, C* = 1.0, ALL RESISTANCE IN TUBES
3 EFFECT OF TUBE LENGTH ON NUMBER OF TUBES, AREA AND PRESSURE DROP
The document discusses feedstock purification in hydrogen plants. It covers reasons for purification such as removing poisons from feedstocks that could damage catalysts. Typical purification systems involve hydrogenation, dechlorination and sulfur removal. Hydrogenation uses catalysts like CoMo or NiMo to react impurities like sulfur compounds and chlorides. Dechlorination requires removing chlorides before sulfur removal since chlorides can poison zinc oxide catalysts used for sulfur removal. Sulfur removal uses zinc oxide catalysts to absorb hydrogen sulfide and other sulfur compounds from feedstocks. The document provides details on typical purification processes and catalyst characteristics.
This document provides an overview of piping and instrumentation diagram (P&ID) development. It discusses the importance of P&IDs and the development process. Key parties involved in P&ID development include engineering, operations, and maintenance. The document also outlines the anatomy of a P&ID sheet and general rules for drawing P&IDs, including showing items, identifiers, and different types of diagrams. Principles of P&ID development include addressing normal and nonroutine operations as well as provisions for maintenance and future changes.
The document discusses inspection of heat exchangers during manufacture. It outlines the key components of a heat exchanger that will be covered, including shells, channels, tube sheets, baffles, tubes, bellows, spacers, and tie rods. Minimum inspection requirements are described for each component, focusing on dimensions, workmanship, materials, and critical points often overlooked. Testing procedures for the completed heat exchanger like hydrotesting and helium leak testing are also summarized.
Mechanical Constraints on Thermal Design of Shell and Tube ExchangersGerard B. Hawkins
Mechanical Constraints on Thermal Design of Shell and Tube Exchangers
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 STANDARD DIMENSIONS
4.1 Shell Diameters
4.2 Tube Lengths
4.3 Tube Diameters
4.4 Tube Wall Thicknesses
5 CLEARANCES
5.1 Tube Pitch
5.2 Pass Partition Lane Widths
5.3 Minimum 'U' Bend Clearance
5.4 Tube-to-Baffle Clearance
5.5 Baffle-to-Shell Clearance
5.6 Bundle-to-Shell Clearance
6 TUBESHEET THICKNESS
7 END ZONE LENGTHS
8 TUBE COUNTS
8.1 Program Correlations
8.2 Use of Tube count Tables
8.3 Graphical Layout
8.4 Use of Computer Programs
8.5 Tie Rods
TABLES
1 HEAT EXCHANGER SHELLS - GEOMETRICAL DATA
FOR INLET & OUTLET BRANCHES: PIPE WITH ANSI
150 FLANGE
2 HEAT EXCHANGER SHELLS - GEOMETRICAL DATA
FOR INLET & OUTLET BRANCHES: PIPE WITH ANSI
300 FLANGE
3 TEMA TIE ROD STANDARDS
FIGURES
1 DEFINITION OF TUBE PITCH, LIGAMENT THICKNESS & PASS PARTITION LANE WIDTH
2 DEFINITION OF PASS PARTITION LANE WIDTH FOR U-TUBES
3 BUNDLE TO SHELL CLEARANCES FOR DIFFERENT BUNDLE TYPES
4 ESTIMATED TUBESHEET THICKNESS FOR FIXED TUBE CONSTRUCTION
5 ESTIMATED TUBESHEET THICKNESS FOR U-TUBE CONSTRUCTION
6 END ZONE
7 EXAMPLE OF OPTU3 GRAPHICAL OUTPUT
Hydrogen Plant Flowsheet - Effects of Low Steam RatioGerard B. Hawkins
Effect of Low Steam Ratio on the Steam Reformer
Effect of Low Steam Ratio on H T Shift & PSA
Effect of Low Steam Ratio on Gross Efficiency
Effect of Low Steam Ratio on Net Efficiency
Alternative schemes for improving heat recovery
Pressure relief devices are important safety components that protect process equipment from overpressure. Standards like the ASME Boiler and Pressure Vessel Code provide guidelines for the proper design, installation, and sizing of relief valves, rupture disks, and other pressure relief devices. These standards help ensure personnel safety and prevent equipment damage in the event excess pressure develops from sources like explosions, fires, or pump failures.
Energy Conservation Opportunities in Cooling Tower.pdfNITIN ASNANI
A cooling tower works by evaporating a portion of circulating water to reject process heat into the atmosphere. It has components like fill media, drift eliminators, nozzles, and fans. Key performance parameters include range, approach, effectiveness, cooling capacity, and cycles of concentration. Cooling tower performance depends on factors like heat load, flow rate, wet bulb temperature, and approach. Proper sizing considers these factors and energy efficiency can be improved through control strategies and opportunities like optimized fan operation.
This document provides an overview of cooling towers. It begins with introductions and definitions, explaining that cooling towers reject heat from condenser water to the ambient air. It then discusses cooling tower fundamentals, components, performance factors like approach and effectiveness. It outlines the heat transfer process. It describes the two main types of cooling towers: natural draft and mechanical draft. Finally, it lists several parameters for assessing cooling tower performance, such as range, approach, effectiveness, cooling capacity, and cycles of concentration.
Thermax Limited provides consulting services for efficient steam systems, including piping design, equipment selection, and design of condensate recovery and waste heat recovery systems. They offer utilities audits to analyze steam, compressed air, cooling, and power systems with the goal of optimizing costs. Their expertise includes selection and sizing of equipment such as pressure reducing stations, traps, and insulation. High-pressure condensate recovery systems can provide fuel savings of 15-20% by recovering heat from flash steam and condensate.
1. The document discusses procedures for calculating pressure safety valve (PSV) sizes for various scenarios that could lead to overpressure. It covers scenarios like closed outlets, external fires, control valve failures, hydraulic expansion, heat exchanger tube ruptures, and power or cooling failures.
2. Calculation methods include enthalpy balances for fractionating columns and the use of relief equations specified in codes like API 521. Worst cases are chosen from all possible scenarios to determine the required PSV size.
3. Key scenarios discussed in detail include closed outlets on vessels, external fires, failures of automatic controls, hydraulic expansion, heat exchanger tube ruptures, total and partial power failures, reflux losses,
Safety is the most important factor in designing a process system. Some undesired conditions might happen leading to damage in a system. Control systems might be installed to prevent such conditions, but a second safety device is also needed. One kind of safety device which is commonly used in the processing industry is the relief valve. A relief valve is a type of valve to control or limit the pressure in a system by allowing the pressurised fluid to flow out from the system.
This document provides an overview of using HTRI software to perform thermal design of heat exchangers. It discusses specifying the geometry, process conditions, and fluid properties required for rating, designing, or simulating shell and tube heat exchangers. Key aspects covered include baffle types, temperature profiles, mean temperature differences, and outputs such as duty, heat transfer area, and pressure drop. The goal is to demonstrate the inputs and calculations used in HTRI to analyze heat exchanger performance.
This document summarizes API STD 521 Part-I, which provides guidance on overpressure protection for refinery equipment. It discusses overpressure causes and protection philosophies. It also lists the minimum recommended contents for relief system designs and flare header calculations. These include analyzing overpressure causes, operating conditions, relief device sizing, and documentation of simulation inputs and outputs. Various overpressure causes are outlined, such as closed outlets, absorbent or cooling failures, accumulation of non-condensables, abnormal heat input, explosions, and depressurizing. Protection measures against these causes like relief valves, rupture disks, and explosion prevention are also mentioned.
The document describes the modified Claus process for sulfur recovery. It discusses the basic Claus reaction and how the modified process improved on it with a free flame oxidation ahead of the catalyst bed and catalytic step revisions, allowing for higher sulfur recovery efficiencies of 90-99.9%. The key steps of the modified Claus process are presented as the combustion step and multiple catalytic steps. Process variations like the straight-through and split-flow configurations are described along with tail gas handling and other sulfur removal processes. Sample calculations are provided to determine the optimum operating parameters for a 80 long ton per day sulfur recovery unit using the modified Claus process.
Alfa Laval owns the global trademarks for MISSIONTM and Alfa Laval. The document discusses Alfa Laval's thermal fluid heating systems, which use circulating oil to transfer heat from fuel-fired heaters to applications like fuel and cargo tanks. Alfa Laval is a global leader in supplying complete thermal fluid systems and has over 30 years of experience in the technology. Their systems offer advantages like high temperature capability, low maintenance, and global after-sales support.
Fired heaters are used to provide heat through the combustion of fuel. They involve combustion fundamentals like the reaction of methane and oxygen. Fired heaters have a furnace design and use draft systems and air preheaters. They employ different types of burners like those used in hot oil heaters and regeneration gas heaters. The start-up process involves inspection, purging, lighting pilots and burners, and adjusting temperatures and flows. Operation requires monitoring air adjustment, temperatures, and addressing potential issues like deposits, failures, or flame-outs. Control strategies manage variables like temperatures, fuels, and flows.
This document provides an overview and summary of a basic training course on petroleum storage tanks. It discusses various tank types including fixed roof tanks, internal floating roof tanks, and floating roof tanks. It covers tank design elements like the structure of the tank bottom and floor, thickness of bottom plates, and attachment of the bottom to the shell. It also addresses tank foundations, including the need for foundations to allow for leak detection. The goals of the training are identified as learning to identify tank types and equipment, understand tank limitations, perform volume calculations, and operate tanks safely.
Air Cooled Heat Exchanger Design
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 SUITABILITY FOR AIR COOLING
4.1 Options Available For Cooling
4.2 Choice of Cooling System
5 SPECIFICATION OF AN AIR COOLED HEAT
EXCHANGER
5.1 Description and Terminology
5.2 General
5.3 Thermal Duty and Design Margins
5.4 Process Pressure Drop
5.5 Design Ambient Conditions
5.6 Process Physical Properties
5.7 Mechanical Design Constraints
5.8 Arrangement
5.9 Air Side Fouling
5.10 Economic Factors in Design
6 CONTROL
7 PRESSURE RELIEF
8 ASSESSMENT OF OFFERS
8.1 General
8.2 Manual Checking Of Designs
8.3 Computer Assessment
8.4 Bid Comparison
9 FOULING AND CORROSION
9.1 Fouling
9.2 Corrosion
10 OPERATION AND MAINTENANCE
10.1 Performance Testing
10.2 Air-Side Cleaning
10.3 Mechanical Maintenance
10.4 Tube side Access
11 REFERENCES
Heaters are used in refineries to raise the temperature of process fluids. There are different types of heaters classified by design and firing method. Key components include tubes, burners, and sections for convection and radiation. Proper draft, excess air, and complete combustion are important for safe and efficient operation. Regular checks help ensure heaters are functioning properly and identify any issues.
This document provides information on fired heaters, including methods of heat transfer, combustion, types of fired heaters, furnace parts, problems that can occur, and introduces several heaters at a refinery. It discusses the three main methods of heat transfer as conduction, convection, and radiation. Fired heaters use combustion of fuel to generate heat that is transferred to process fluids through tubes. Box and cylindrical designs are described. Key furnace parts and issues like overfiring, vibration, and inefficiency are outlined. Example heaters at the refinery include crude, vacuum, visbreaker, and hydrotreating unit heaters.
Thermal Design Margins for Heat Exchangers
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 TERMINOLOGY
5 REASONS FOR SPECIFYING A DESIGN MARGIN
5.1 Instantaneous Rates
5.2 Future Uprating
5.3 Plant Upsets
5.4 Process Control
5.5 Uncertainties in Properties
5.6 Uncertainties in Design Methods
5.7 Fouling
6 COMBINATION OF DESIGN MARGINS
7 CRITICAL AND NON-CRITICAL DUTIES
7.1 General
7.2 Penalties of Over-design
8 OPTIMIZATION OF EXCHANGER DUTY
9 WAYS OF PROVIDING DESIGN MARGINS
9.1 The Provision of Excess Surface
9.2 Decreasing the Design Temperature Difference
9.3 Increasing the Design Process Throughput
9.4 Increasing the Design Fouling Resistance
9.5 Reducing the Design Process Outlet Temperature Approach
9.6 Adjusting the Physical Properties
10 ACCURACY OF THE DESIGN METHODS FOR SHELL AND TUBE EXCHANGERS
10.1 Pressure Drop
10.2 Heat Transfer
11 SUGGESTED DESIGN MARGINS
11.1 No Phase Change Duties
11.2 Condensers
11.3 Boilers
12 EFFECT OF UNDER- OR OVER-SURFACE ON PERFORMANCE
FIGURES
1 EFFECT OF LENGTH ON EXCHANGER DUTY COUNTERCURRENT FLOW, C* = 1.0
2 EFFECT OF NUMBER OF TUBES ON EXCHANGER PERFORMANCE COUNTERCURRENT FLOW, C* = 1.0, ALL RESISTANCE IN TUBES
3 EFFECT OF TUBE LENGTH ON NUMBER OF TUBES, AREA AND PRESSURE DROP
The document discusses feedstock purification in hydrogen plants. It covers reasons for purification such as removing poisons from feedstocks that could damage catalysts. Typical purification systems involve hydrogenation, dechlorination and sulfur removal. Hydrogenation uses catalysts like CoMo or NiMo to react impurities like sulfur compounds and chlorides. Dechlorination requires removing chlorides before sulfur removal since chlorides can poison zinc oxide catalysts used for sulfur removal. Sulfur removal uses zinc oxide catalysts to absorb hydrogen sulfide and other sulfur compounds from feedstocks. The document provides details on typical purification processes and catalyst characteristics.
This document provides an overview of piping and instrumentation diagram (P&ID) development. It discusses the importance of P&IDs and the development process. Key parties involved in P&ID development include engineering, operations, and maintenance. The document also outlines the anatomy of a P&ID sheet and general rules for drawing P&IDs, including showing items, identifiers, and different types of diagrams. Principles of P&ID development include addressing normal and nonroutine operations as well as provisions for maintenance and future changes.
The document discusses inspection of heat exchangers during manufacture. It outlines the key components of a heat exchanger that will be covered, including shells, channels, tube sheets, baffles, tubes, bellows, spacers, and tie rods. Minimum inspection requirements are described for each component, focusing on dimensions, workmanship, materials, and critical points often overlooked. Testing procedures for the completed heat exchanger like hydrotesting and helium leak testing are also summarized.
Mechanical Constraints on Thermal Design of Shell and Tube ExchangersGerard B. Hawkins
Mechanical Constraints on Thermal Design of Shell and Tube Exchangers
0 INTRODUCTION/PURPOSE
1 SCOPE
2 FIELD OF APPLICATION
3 DEFINITIONS
4 STANDARD DIMENSIONS
4.1 Shell Diameters
4.2 Tube Lengths
4.3 Tube Diameters
4.4 Tube Wall Thicknesses
5 CLEARANCES
5.1 Tube Pitch
5.2 Pass Partition Lane Widths
5.3 Minimum 'U' Bend Clearance
5.4 Tube-to-Baffle Clearance
5.5 Baffle-to-Shell Clearance
5.6 Bundle-to-Shell Clearance
6 TUBESHEET THICKNESS
7 END ZONE LENGTHS
8 TUBE COUNTS
8.1 Program Correlations
8.2 Use of Tube count Tables
8.3 Graphical Layout
8.4 Use of Computer Programs
8.5 Tie Rods
TABLES
1 HEAT EXCHANGER SHELLS - GEOMETRICAL DATA
FOR INLET & OUTLET BRANCHES: PIPE WITH ANSI
150 FLANGE
2 HEAT EXCHANGER SHELLS - GEOMETRICAL DATA
FOR INLET & OUTLET BRANCHES: PIPE WITH ANSI
300 FLANGE
3 TEMA TIE ROD STANDARDS
FIGURES
1 DEFINITION OF TUBE PITCH, LIGAMENT THICKNESS & PASS PARTITION LANE WIDTH
2 DEFINITION OF PASS PARTITION LANE WIDTH FOR U-TUBES
3 BUNDLE TO SHELL CLEARANCES FOR DIFFERENT BUNDLE TYPES
4 ESTIMATED TUBESHEET THICKNESS FOR FIXED TUBE CONSTRUCTION
5 ESTIMATED TUBESHEET THICKNESS FOR U-TUBE CONSTRUCTION
6 END ZONE
7 EXAMPLE OF OPTU3 GRAPHICAL OUTPUT
Hydrogen Plant Flowsheet - Effects of Low Steam RatioGerard B. Hawkins
Effect of Low Steam Ratio on the Steam Reformer
Effect of Low Steam Ratio on H T Shift & PSA
Effect of Low Steam Ratio on Gross Efficiency
Effect of Low Steam Ratio on Net Efficiency
Alternative schemes for improving heat recovery
Pressure relief devices are important safety components that protect process equipment from overpressure. Standards like the ASME Boiler and Pressure Vessel Code provide guidelines for the proper design, installation, and sizing of relief valves, rupture disks, and other pressure relief devices. These standards help ensure personnel safety and prevent equipment damage in the event excess pressure develops from sources like explosions, fires, or pump failures.
Energy Conservation Opportunities in Cooling Tower.pdfNITIN ASNANI
A cooling tower works by evaporating a portion of circulating water to reject process heat into the atmosphere. It has components like fill media, drift eliminators, nozzles, and fans. Key performance parameters include range, approach, effectiveness, cooling capacity, and cycles of concentration. Cooling tower performance depends on factors like heat load, flow rate, wet bulb temperature, and approach. Proper sizing considers these factors and energy efficiency can be improved through control strategies and opportunities like optimized fan operation.
This document provides an overview of cooling towers. It begins with introductions and definitions, explaining that cooling towers reject heat from condenser water to the ambient air. It then discusses cooling tower fundamentals, components, performance factors like approach and effectiveness. It outlines the heat transfer process. It describes the two main types of cooling towers: natural draft and mechanical draft. Finally, it lists several parameters for assessing cooling tower performance, such as range, approach, effectiveness, cooling capacity, and cycles of concentration.
This document discusses the design of a 10,500-ton central chilled water plant in Washington D.C. Several design options were evaluated using life-cycle cost analysis. The selected design used a series-series counterflow arrangement of six electric centrifugal chillers with dual refrigerant circuits. This configuration reduced chiller power demands and pumping costs, resulting in the lowest life-cycle cost that was over $1.4 million less than parallel arrangements. The series-series counterflow design lowers the 'lift' required of the chillers by staging the evaporator and condenser temperatures between units.
Case study Energy Audit for Chiller PlantHina Gupta
The document discusses energy audits conducted on HVAC equipment at a client site by MGCS-Energy Audit Company. It analyzes the performance of two chillers and two cooling towers. For the chillers, it is found that Chiller 2 has a higher condenser approach and lift, indicating its condenser is fouled. Cleaning the condenser is recommended to improve Chiller 2's efficiency. For the cooling towers, Tower 2 has a higher approach and lower effectiveness, suggesting relocating the towers to the terrace for better air flow. The audits identify opportunities for energy savings through equipment maintenance and modifications.
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As run energy efficiency of cooling towersD.Pawan Kumar
This document discusses factors that affect the energy efficiency of cooling towers, including entering wet bulb temperature, cooling range, effectiveness, and approach temperature. It notes that simultaneous achievement of maximum range, capacity, and effectiveness with lowest input energy is desirable. The performance of cooling towers in actual operation should be assessed against design conditions and performance curves. Key factors to examine include heat load, water flow, fan power, range, and effectiveness. Optimizing factors like fan operation, cycles of concentration, drift eliminators, and load segregation can improve efficiency.
This document provides information about cooling towers, including:
1. Cooling towers reduce water temperature by bringing water and air into direct contact, with some water evaporating to cool the rest.
2. Key components include fill materials to maximize contact between water and air, nozzles to distribute water, and fans to pull air through.
3. Cooling tower performance is evaluated based on parameters like range, approach, and efficiency. Opportunities to improve energy efficiency include selecting an appropriately sized tower, optimizing fill materials and water distribution, and improving fans and pumps.
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This document discusses predicting the cold water temperature of a cooling tower under different conditions. It begins by explaining cooling tower theory and the accepted performance equation. It then shows how to calculate the tower characteristics (NTU) at design conditions using the Merkel equation. This involves calculating parameters like L/G ratio, enthalpy differences, and incremental NTU values. The example calculates the design tower characteristic (NTU) of 1.367 for a cooling tower in Mumbai with given design temperatures. It further demonstrates how to predict the new tower characteristic if the wet bulb temperature changes while other factors remain constant.
This document discusses various ways to optimize water-cooled cooling systems to reduce energy use. It describes how the efficiency of individual components like chillers and cooling towers has improved over time but greater savings are possible by optimizing overall system design and operation. Some strategies discussed include modulating cooling tower fan speed based on load to balance chiller and fan energy use, using closer cooling tower approach temperatures to lower chiller energy, controlling multi-cell tower fans simultaneously at lower speeds, and optimizing condenser water flow. Proper implementation of these strategies can significantly reduce cooling system energy use.
This document discusses water-side heat recovery from chillers. It provides context on the history of heat recovery use in the 1970s during an energy crisis and its renewed interest today due to rising energy costs and environmental regulations. It then covers various types of heat recovery systems using single or dual condenser chillers, appropriate water temperatures for heat recovery, and the impact of heat recovery on chiller capacity and efficiency depending on compressor type. The optimal approach is to recover heat at the lowest possible temperature to satisfy loads while minimizing additional chiller energy use.
This document discusses the design and analysis of cooling towers. It begins with a brief history of cooling tower design and the development of theories to analyze them. It then discusses key parameters that describe cooling tower performance such as range, approach, and water/air ratio. The document outlines methods for analyzing cooling tower performance, including the Merkel method and global conservation equations. It also discusses factors that affect heat transfer in cooling towers and how tower characteristics are determined. Finally, it covers other important design considerations like pressure drops, fan power requirements, and water losses through evaporation and drift.
This document appears to be a project report on the thermal design of an evaporative condenser. It includes an abstract that summarizes calculating the design parameters of an evaporative condenser for a refrigeration unit at a dairy plant. It then discusses the refrigeration system arrangement at the plant site, calculations performed to determine the condenser design, and results and conclusions. The report was submitted by 4 students for their Bachelor's degree in partial fulfillment of project requirements.
Development of a Bench-Top Air-to-Water Heat Pump Experimental ApparatusCSCJournals
The document describes the development of a bench-top air-to-water heat pump experimental apparatus for educational purposes. Key features include:
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The document summarizes a study on recovering waste heat from an air conditioning system. It discusses:
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3) Technical specifications of the air conditioner used in the study are provided, and the design process is outlined. This includes calculating the refrigeration effect, available desuperheating heat, and mass flow
Homeowners with natural gas water heaters have difficulty justifying the expense of a more efficient condensing heater. Combination space and domestic hot water systems bundle together the two loads, which saves energy and makes them more cost-effective. These systems also help eliminate combustion safety concerns.
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1. Chevron Corporation 2200-1 December 1989
2200 Cooling Tower Design Guidelines
Abstract
This section discusses key cooling tower design parameters, electrical facility instal-
lation, environment/safety/fire protection considerations, and forebay design.
Contents Page
2210 Key Parameters 2200-2
2211 Heat Load (Duty)
2212 Circulating Water Rate (GPM)
2213 Wet Bulb Temperatures
2214 Optimizing Cooling Tower Costs
2215 Makeup Water
2216 Blowdown and Cycles of Concentration
2220 Electrical Installations 2200-10
2221 Area Classification
2222 Materials
2223 Installation
2230 Environmental/Safety/Fire Protection Considerations 2200-11
2231 Effluent Quality
2232 Air Quality
2233 Safety
2234 Fire Protection
2240 Cooling Tower Forebay Design 2200-16
2241 General Information
2242 Forebay Design
2243 Hydraulic Model Testing
2244 Standard Drawings
2245 References
2. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-2 Chevron Corporation
2210 Key Parameters
This section discusses the key design parameters that must be considered when
purchasing or rating a cooling tower. The actual rating procedure is in Section 2300.
2211 Heat Load (Duty)
The tower duty is calculated using the following equation:
Duty Q MMBH = m⋅Cp ⋅ (Th - Tc)
(Eq. 2200-1)
where:
m = Circulation water flow in pounds per hour.
Cp = Specific heat in Btu/lb⋅°F
Th = Hot water to the tower, °F
Tc = Cold water from the cooling tower basin, °F
Converting pounds per hour to gallons per minute and using a Cp of 1,
Q (MMBH) = 500 ⋅ GPM ⋅ (Th - Tc)
The 500 comes from converting Item 1 from GPM to lb/hr: (8.33 lb/gal ⋅ 60 min/hr)
= 500.
The calculated heat load is usually increased by a factor of 10 to 20% to obtain the
design heat load.
2212 Circulating Water Rate (GPM)
Conversely, if we have the duty and we want to find the circulating water rate
assuming a temperature range:
(Eq. 2200-2)
The circulation rate and temperatures are developed by looking at:
1. All the heat exchanger duties in the cooling tower network.
2. The cooling water flow rates and temperatures to satisfy the design conditions
for the heat exchangers.
By summing all the duties of the heat exchangers in the network and taking the
weighted averages of all the inlet and outlet temperatures of the circulating water in
GPM, Th and Tc can be determined. For each circulating water rate there is a
unique hot and cold water temperature combination.
GPM
Q
500 Th Tc
–
( )
-------------------------------
-
=
3. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-3 December 1989
2213 Wet Bulb Temperatures
Determining the design wet bulb temperature is an important decision, as invest-
ment costs are involved. Figure 2200-1 lists the ambient design wet bulb tempera-
tures at a number of our operating centers.
Considerations for Design Wet Bulb
1. Cooling towers should be oriented so that the longitudinal axis is aligned with
(parallel to) the prevailing wind. If the plot plan will not accommodate this
orientation, the wet bulb temperature shown in Figure 2200-1 may need to be
increased by 1°F.
2. Cooling tower performance can be measurably affected by external influences
on the wet bulb temperature of the air entering the tower. Examples of this are
localized heat sources situated upwind, drift from adjacent cooling towers,
recirculation of exit air caused by large structures adjacent to the tower, etc.
For more information on recirculation, request a copy of CTI Bulletins PFM-
110 and PFM-116. The external influences discussed here should be evaluated,
and if appropriate, shown wet bulb design temperatures may need to be raised
an additional 2°F.
Fig. 2200-1 Design Wet Bulb Temperatures at Several Company Locations
Location Design Wet Bulb °F
Anchorage, Alaska 59
Bahamas, Freeport 79
Cedar Bayou (Bayport, Texas) 82
El Paso, Texas 70
El Segundo, California 70
Hawaii 73
Kaybob 61
Marietta, Ohio 77
Mt. Belvieu (Bayport, Texas) 82
Orange, Texas 80
Pascagoula, Mississippi 79
Philadelphia, Pennsylvania 76
Port Arthur, Texas 82
Richmond, California 65
Salt Lake, Utah 65
St. James, Louisiana 80
St. John, N. B. 65
Vancouver (Burnaby) 68
4. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-4 Chevron Corporation
If a cooling tower is being located where the Company has no experience, the
design wet bulb temperature should be obtained from the local weather bureau or
local airports. Industry’s normal practice is to use the wet bulb temperature at the
5% level. This is the temperature that the wet bulb will be below over 95% of the
time during the summer months.
2214 Optimizing Cooling Tower Costs
For a given heat duty and design wet bulb temperature, you can use the following
three parameters to optimize the cooling tower cost.
1. The temperature of the water returning to the tower.
2. The range—the difference in temperature between the hot water returning to
the tower and the cold water from the cooling tower basin. (Cooling ranges
normally fall between the limits shown in Figure 2200-2.)
3. The approach—the difference in temperature between the cold water from the
cooling tower basin and the ambient wet bulb temperature.
Tower Size Factor
The tower size factor is an empirical way of comparing various combinations of the
parameters discussed above. Figure 2200-3 plots the “Tower Size Factor” for
assumed returned water temperatures, known wet bulb temperatures, and resultant
ranges and approaches. The return temperature, range and approach that satisfy the
process and project limitations and result in the lowest “Tower Size Factor” will
also result in the lowest cooling tower costs.
Example:
Assume this is Hawaii, with a temperature of water back to the tower of 118°F and
a wet bulb temperature of 73°F (118 − 73 = 45). Move vertically up the chart at 45
to the range of 35°F, or an approach of 10°F, which is consistent mathematically.
Move horizontally to the left to the design wet bulb temperature; then move down
to the left, following the curves to the “Tower Size Factor.” For our example, the
Tower Size Factor is about 0.93.
Fig. 2200-2 Acceptable Cooling Tower Temperature Range for Different Types of Plants
Type of Plant Range, °F
Refineries 25-45
Power Plant Steam Condensing 10-25
Chemical Processes 15-25
Air Conditioning/Refrigeration 5-10
6. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-6 Chevron Corporation
Determine If the Tower Meets Design Requirements
It is easy to determine if the tower meets design requirements because of the effort
the CTI has put into resolving past problems that cooling tower manufacturers have
had with their completed towers meeting design criteria.
Our Specification EXH-EG-1317 itemizes the following as the sole responsibility
of the vendor:
1. Meet the operating conditions of the Data Sheet (EXH-DS-1317—CTI Bid
Form).
2. Be certain that the tower is a CTI code tower.
3. Meet all applicable codes and ordinances.
In addition to these requirements, the purchase order should require the manufac-
turer to supply the appropriate data so that a CTI Acceptance Test under ATC-105
can be performed (with appropriate equations to financially penalize the manufac-
turer if the tower does not meet “design.”)
2215 Makeup Water
Water losses (and consequently makeup water rate) from a cooling tower are the
sum of:
1. Evaporation. The cooling tower “cools,” mainly by evaporation. To approxi-
mate this loss, use 1% of the circulation rate for each 10 degrees Fahrenheit of
cooling.
2. Drift. This is the water that leaves the tower with the air. In the past the
maximum drift was specified at 0.2% of the water circulated. With modern
advances in drift elimination, this has been significantly reduced. For towers
purchased in early 1989 we have been receiving guarantees of 0.008% of the
circulation rate for drift loss. This loss carries the impurities that are in the
water and the chemicals added in the water treatment program. See
Section 2230 for the environmental concerns for drift.
The rate of water through the fill material (“Water Loading”) for most of our
towers is about 4 GPM/ft2. Drift is not dependent on water loading. Increasing
air velocity does result in greater drift. Typical air flows in cooling towers are
300 to 700 ft/min. Velocities in the stack are in the range of 1500 to 2000
ft/min.
3. Blowdown. This is the one water loss of the three that is adjustable, once the
tower is running. It controls the “cycles of concentration.”
2216 Blowdown and Cycles of Concentration
Blowdown from a circulating water system is necessary to prevent scale-forming
compounds from exceeding their respective solubilities. If water is not removed
from the system, the dissolved solids present in the make-up will concentrate and
7. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-7 December 1989
deposition will take place. A high total dissolved solids (TDS) level also increases
the system corrosiveness. On the other hand, from an economic viewpoint, it is
desirable to minimize blowdown in order to minimize water usage. Cycles of
concentration is the term employed to indicate the degree of concentration of the
circulating water as compared to the makeup. For example, two cycles of concentra-
tion indicate the circulation water has twice the solids concentration of the makeup
water. Cycles are usually based on concentration of chloride (where water is not
chlorinated) or magnesium and sodium ions (because they almost never precipitate
under operating conditions). The chemical suppliers can also run soluble calcium
concentration to determine cycles.
Blowdown Equations
Blowdown rates from a circulating water system can be calculated using the
following equations:
Mu = E + Bd + W = E ⋅ C/(C-1)
(Eq. 2200-3)
C = E + Bd + W/Bd = Stw/Smu
(Eq. 2200-4)
Bd = E / (C - 1)
(Eq. 2200-5)
where:
Mu = Makeup, GPM
E = Evaporation loss, GPM
Bd = Blowdown, GPM
W = Drift loss, GPM
C = Cycles of concentration (defined below)
Stw = Solids concentration in tower water
Smu = Solids concentration in makeup water
For each unit of total dissolved solids (TDS) added with the makeup, one unit of
TDS must be removed as blowdown. We have:
Smu ⋅ Mu = Stw ⋅ Bd
(Eq. 2200-6)
or
Stw/Smu = Mu/Bd = C
(Eq. 2200-7)
8. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-8 Chevron Corporation
Example of Blowdown and Cycles of Concentration Calculations
Calculations:
E = 13,000 ⋅ (0.1/10°) ⋅ 35° = 455 GPM
(Eq. 2200-8)
Note Evaporation is usually 1% of circulation rate for each 10°F change across
the tower.
(Eq. 2200-9)
Bd = Mu - E = 569 - 455 = 114 GPM.
Assuming W = 0.
(Eq. 2200-10)
Figure 2200-4 shows the reduction of blowdown for the example above with
increased cycles of concentration. The law of diminishing returns starts to apply at
the higher cycles. However, minimizing the blowdown is very desirable in a zero
effluent discharge location. Blowdown can also be expressed as a percent of the
makeup flow rate. In this example,
% Bd = (114/569) ⋅ 100 = 20%
(Eq. 2200-11)
Sizing Acid and Inhibitor Systems
The above equations can also be used when sizing inhibitor and sulfuric acid
pumps. In both cases, it is necessary to know the makeup water rate to the system.
This rate, together with cycles of concentration, is used to calculate the inhibitor
and acid consumption. For calculation purposes, the amount of corrosion inhibitor
required to be added to the makeup water is the total inhibitor level desired in the
system divided by the cycles of concentration. For example, if 50 ppm are recom-
mended for the circulating water, then 10 ppm are added to the makeup water if the
system is cycled five times.
Multiplying this makeup dosage in ppm by the millions of pounds of makeup per
day will result in the pounds of inhibitor requirements. In the above example, the
daily makeup rate is 569 gallons per minute or 6.8 million pounds/day. Multiplying
this by 10 ppm, the daily inhibitor requirement amounts to 68 pounds.
Given: Circulation rate = 13,000 GPM
Delta T = 120°F - 85°F = 35°F
Cycles of concentration = 5
Mu
C E
⋅
C 1
–
------------
-
5 455
×
4
-----------------
- 569 GPM
= = =
9. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-9 December 1989
Fig. 2200-4 Example: Blowdown vs. Cycles of Concentration
10. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-10 Chevron Corporation
2220 Electrical Installations
Cooling towers present special problems for the installation of electrical facilities.
Moist, corrosive conditions normally exist; hence, moisture-andcorrosion-resistant
materials are required. In addition, because flammable gases or vapors may be
present under some conditions, equipment suitable for the appropriate hazardous
area classification is required.
Standard Drawing GD-P1011 shows the typical area classification requirements
and installation details and lists recommended materials.
2221 Area Classification
Leaks in water-cooled heat exchangers will normally result in leakage of process
fluid into the cooling water. If the process fluid is a gas or a hydrocarbon liquid
with a flash point lower than the cooling water temperature, gas or vapor will be
released from the cooling water at the tower. In case of a tube rupture in a high-pres-
sure gas heat exchanger, large quantities of gas will be entrained in the water. This
gas may cause pressure surges in the cooling water return line that may rupture the
cooling water piping on the tower. Thus, it is possible for flammable gases or
vapors to be released at the cooling tower, sometimes in large quantities.
However, an abnormal condition involving equipment failure must exist—i.e., a
leak in a heat exchanger—in order for flammable gases or vapors to be present at a
cooling tower. Thus, the appropriate classification is Class I, Division 2.
2222 Materials
Because of the corrosion problem, aluminum conduits and fittings should be used.
Electrical equipment enclosures should be aluminum or corrosion-resistant mate-
rials. For corrosion resistance, all aluminum materials should have a copper content
of less than 0.4%.
Typical Class I, Division 2, wiring methods should be used. Conduits should be of
rigid metal with threaded connections. Fittings should have threaded hubs and cast
gasketed covers. Push buttons should be explosionproof, and vibration switches
should be hermetically sealed (mercury type) in cast enclosures, or explosionproof.
Receptacles should be explosionproof, of the arc-tight type designed so that arcs
will be confined within the case of the receptacle. Lights should be enclosed and
gasketed. Conduit seals should be provided as normally required in classified areas.
2223 Installation
Installation details shown on Standard Drawing GD-P1011 should be used. Wher-
ever practical, conduits should be routed on the exterior of the tower. However, the
conduit may be run below the upper deck if required. Conduit runs across the upper
surface of the deck can be ramped over. In all cases, the conduits should be
routed away from any cooling water piping that might move during upset
conditions and cause damage to conduits and fillings.
11. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-11 December 1989
2230 Environmental/Safety/Fire Protection Considerations
2231 Effluent Quality
Chromate vs. Nonchromate Corrosion Inhibitors
Environmental regulations are forcing drastic limitations on or elimination of the
chromium in waste water. The National Pollution Discharge Elimination System
(NPDES) and the Environmental Protection Agency (EPA) limit the discharge of
total and hexavalent chromium from our process plants.
Cooling tower blowdown constitutes a large portion of a typical plant’s waste water.
The alternatives are either chromium removal from cooling tower blowdown or the
use of an alternative ultra-low or nonchromate treatment. Chromate
removal/recovery equipment on cooling tower blowdown streams is usually more
expensive than nonchromate inhibition. However, automatic control of chemical
concentrations and an excellent microbiological program are a must for a nonchro-
mate program to perform successfully.
Nonchromate treatments can be expected to reduce corrosion on mild steel only
down into the range of 3 to 5 mils per year. Even with higher corrosion rates, the
cost of nonchromate treatments run from 1.5 to 2.0 times the cost of a chromate-
based treatment program.
The selection of the proper corrosion inhibitor should be made by the process plant
on an individual basis based on economics and operational reliability. Section 2400
and Appendix J give guidelines on the various corrosion inhibitor systems.
Minimizing Blowdown
Minimizing blowdown makes sense from both an economic and environmental
standpoint. Depending on the location, makeup water costs can range from 40 cents
to $4.00 per 1000 gallons.
Normally, the plant effluent systems are capable of handling cooling tower blow-
down streams. However, if large volumes of cooling tower blowdown must be
disposed of and the blowdown contains high levels of total dissolved solids (TDS)
and metal-based water treating chemicals, this practice may be unsatisfactory.
Possible future Best Available Technology (BAT) Effluent Regulations may also
require a reduction in effluent flow rate. For these reasons, methods of minimizing
cooling tower blowdown are being investigated.
Typically, cooling tower blowdown is composed of less than 0.5% by weight of
dissolved solids. The cost of disposal by such means as solar ponds, evaporation
plants, and deep well injections depends on the volume discharged. Other blow-
down treating methods, such as chrome removal processes (which the Company has
not used to date) are also dependent on the volume. Therefore, every effort should
be made to minimize the amount of water going to ultimate disposal. Other special
processes are side stream softening or side stream softening combined with an elec-
12. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-12 Chevron Corporation
trodialysis or reverse osmosis unit. The clean effluent from these processes can be
recycled to the tower to reduce the amount of cooling tower blowdown.
Blowdown is discussed in detail in Section 2216 and Section 2422.
Use of Biocides
In some areas, effluent must meet fish toxicity requirements. Biocides can be toxic
to fish and must be used with care. They should be chosen so that a minimum
amount is used with a maximum potential for degradation in the effluent system.
Biocides may also have an adverse effect on the water treatment systems. A rough
indication of this can be obtained by comparing the biological oxygen demand
(BOD) for a sample of normal effluent water and a sample of effluent containing
biocide at the concentration expected in the effluent. A low BOD result in the pres-
ence of biocide indicates a potential toxicity problem. These tests should be
conducted before a new biocide is used.
Impounds Around Chemical Areas
As discussed in Section 2530, all chemical injection facilities should be contained
by berms. The impoundage should be large enough to hold the contents of the
largest container in case of a rupture.
2232 Air Quality
Drift
The drift off the cooling tower contains solids and other additives in proportion to
the level of solids and additives in the recirculating water. The most significant
contaminant is hexavalent chromium (Cr+6
) if it is being used as a corrosion inhib-
itor. Hexavalent chromium emissions can be controlled by:
1. Limiting the average chromate concentration in the recirculating water (pres-
ently 13 ppm maximum in the petroleum and chemical industries).
2. Eliminating chromate-based chemical completely from the water treating
programs.
3. Retrofitting towers with higher efficiency drift eliminators.
4. A combination of 1 and 3 above.
Minimizing Drift
Manufacturers claim they can guarantee drift rates from 0.02% down to 0.001% of
the recirculation rate. To achieve the lower drift numbers requires some additional
investment and 3% to 5% added fan horsepower. These low numbers are difficult to
measure. The measuring techniques vary and several different sampling train config-
urations have been developed. The drift rates have not given consistent results.
13. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-13 December 1989
2233 Safety
Chemical Handling
The safety considerations for handling water treatment chemicals and chlorine are
discussed in Section 2500.
Wood Deterioration
Wood deterioration in platforms and stairs has been a problem. Decay organisms
also affect the nonwater wetted areas of the cooling tower. All cooling towers
should be inspected regularly for any signs of cracking or deterioration. This is
particularly critical for towers where pressure-treated Douglas fir and non-heart-
wood redwood are the principal materials of construction. These two types of wood
have a history of deterioration and therefore higher maintenance costs.
Fan Vibration
Excessive fan or gearbox vibration has caused many fan failures. Obviously, this
can be a significant personnel hazard. The primary purpose of cooling tower vibra-
tion switches is to detect high fan/gearbox vibration and shut down the fan motor
before a failure occurs. A secondary purpose of the switch is to allow surveillance
of machine condition in operation so that failures can be predicted ahead of time
and preventive maintenance performed. While mechanical switches have proven
inadequate in meeting the primary purpose and incapable of providing the second
purpose, electronic monitor/switches can meet both requirements.
Mechanical vs. Electronic Switches. After tests in 1987 comparing the commonly
used mechanical switch (Metrex 5175-01) and an electronic switch (PMC Beta
Model 440), Richmond Refinery is now recommending the use of electronic
switches for cooling tower fans. For more information on this testing, please
contact the Richmond Refinery IMI group and request the 1/31/89 report entitled
“FCC Cooling Tower Electronic Vibration Switches.”
Previously, cooling tower fans at Richmond Refinery have been equipped with
mechanical vibration switches (Metrix Model 5175-01 or Robertshaw Model 365
Vibraswitch). Recent experience has shown these mechanical switches provide inad-
equate protection against catastrophic failures of cooling tower fans. Alternatively,
electronic switches provide all of the following essentials for protective shutdowns:
• Good sensitivity and repeatability at generated vibration frequencies (espe-
cially low frequencies, 3 to 30 Hz)
• Transducer mounted on gearbox housing for good signal detection (not on
auxiliary piping or cooling tower structure where the vibration signal is attenu-
ated)
• Testing capability with fan running
• Time delay or shutdown bypass for startups
• Remote reset capability
14. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-14 Chevron Corporation
Mechanical switches cannot be mounted on the gearbox and are not testable on-the-
run because mechanical switches do not have a remote test function. Furthermore,
bench tests have shown that, even with new mechanical switches, sensitivity and
repeatability are inadequate to detect destructive vibrations.
In addition to the above vibration switch essentials, electronic switches provide the
following features to meet the secondary purpose of applying predictive mainte-
nance techniques:
• AC output for monthly surveillance
• 4 to 20 mA output for remote vibration monitor/recorder
Mechanical switches are self-contained and are not designed to have these capabili-
ties.
Installation. Richmond Refinery now uses the PMC Beta Model 450 (see
Figure 2200-5 for the specifications and settings Richmond uses for these
switches.) Other manufacturers offer similar switches.
Switch electronics are mounted on the cooling tower in explosionproof housings.
Four of 14 switches mounted at Richmond had corrosion problems on PC boards
attributed to moisture intrusion during installation. Long term reliability of elec-
tronics in this environment has yet to be proven. Currently, the PMC Beta switches
are fully operational and are providing continuous protection and gearbox vibration
data via the DC Plus data collector.
Maintenance. Perform periodic maintenance (every 3 months) in conjunction with
monthly vibration monitoring functions.
Change Corrosion Inhibitor Packet. Due to the moist environment, corrosion inhib-
itors are installed in the housings of the transformer/power supply, vibration switch,
and transducer. Corrosion inhibitor: Hoffman Corrosion Inhibitor, Part No. A-HCI-
1DV, size 0.25" × 1.25" × 3".
Relubricate Housing Threads with Grease. Housing cover threads corrode and
must be coated with Crouse-Hinds Anti-Seize Screw Thread Lubricant Sealer, Part
No. STL-2.
Reference—Johnson, C. W., “FCC Cooling Tower Electronic Vibration Switches,”
1/31/89, IMI, Richmond Refinery.
Safety Considerations
1. When working on mechanical equipment (like the fan), utilize the electrical
lock-out feature.
2. Cooling tower fill and drift eliminators are not safe working surfaces. They
should be evaluated from existing access walkways, from air inlet openings, or
from temporary planking that spans column lines.
3. A “buddy” system should be used whenever entering any part or hatch on a
cooling tower. Only qualified people familiar with the mechanical components
and understanding the safety hazards should inspect the tower.
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Chevron Corporation 2200-15 December 1989
4. Always replace coupling guards before putting any cooling tower cell back
into service.
5. In cold climate locations, ice formation can damage tower components and be
a safety hazard. Icing procedures should be available and in good working
condition, anytime the temperature drops to around 40°F.
2234 Fire Protection
Nearly all of our cooling towers are made of wood and, because we are cooling
hydrocarbons in most of the exchangers, have wooden splash fill. Cooling towers
are fire hazards, particularly when idle. Recommendations for fire protection are as
follows:
1. Prohibit smoking, open lights, and warm-up fires anywhere near the tower.
2. Supervise closely any welding or cutting operations.
3. Locate new cooling towers remote from any equipment that produces sparks.
Fig. 2200-5 FCC Cooling Tower Vibration Switches, Specifications and Settings
Manufacturer:
PMC Beta Corporation
4 Tech Circle
Natick, MA 01760
(617) 237-6920
Model: PMC Beta, Model 450 D-R supplied with:
• 480 VAC input transformer (L1 & L2 of 480 V System)
• 480 VAC 3 Amp Relay for Shutdown Circuit
• 0.1 to 1.5 in/sec range
• AC output on BNC Connector on Switch Panel
• AC output sensitivity = 278 MV/in/sec
Starting Lockout Terminals
3/4 FNPT connections drilled at right, left, bottom
Model 160 E transducer
Field-Configurable Settings for Cooling Tower Gearboxes:
Shutdown setpoint = 0.4 to 0.5 in/sec
Alarm Setpoint = 60% to 80%
Shutdown Relay = Normally closed (NC)
Alarm Relay = Not used
Shutdown Relay Time Delay = 3 seconds
Alarm Relay Time Delay = 3 seconds
Remote Reset = Not used
16. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-16 Chevron Corporation
4. Provide hydrants with adequate pressure and hoses to reach all sections of the
cooling tower.
5. Install fire sprinkler systems that automatically deluge any fire source.
2240 Cooling Tower Forebay Design
This section provides basic concepts and guidelines for cooling tower forebay
design. Past experience has shown that a poorly designed cooling tower forebay
will severely impact cooling tower operation and pump life because of the
following associated problems:
• Pump cavitation
• Pump vibration
• Pump equipment damage
• Reduced pump efficiency
• Excessive noise
Good design is especially important when large pumps (over 300,000 GPM) are
used; large pumps are more susceptible to rough running and vibration, and thus
require “better” forebay conditions for satisfactory performance.
Accordingly, the following standards are applicable to forebays equipped with
either horizontal or vertical pumps of the following capacities:
• 3000 to 300,000 GPM
• 300,000 GPM and greater
These standards do not apply to facilities with pump capacities less than 3000
GPM, because small pumps are not usually used in cooling tower forebay applica-
tions.
These design guidelines may also apply to facilities with the same function as a
forebay, e.g., pumping station sumps. For facilities with pump capacity less than
3000 GPM, facility design should follow the pump manufacturer’s recommenda-
tions.
The information in this section is based on research conducted by the Hydraulic
Institute and British Hydromechanics Research Association. Forebay designs
should be analyzed using a hydraulic model; most models are efficient, relatively
inexpensive, and reliable.
2241 General Information
The forebay is an intake structure that collects and supplies a flow of water to the
suction point of the circulation pumps. The flow conditions that govern pump
performance are a function of the hydraulic design and upstream approach flow. A
“good” forebay design results in a uniform, steady, single phase flow and satisfac-
tory pump performance.
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Chevron Corporation 2200-17 December 1989
Conversely, inadequate design may cause adverse flow conditions and hydraulic
problems such as uneven flow distribution and large scale turbulence. The most
damaging conditions, however, are vortices near the pump column (vertical pumps)
and in the corners and along the walls and floor of the forebay. Even a small
amount of air entrained in the vortices will cause pump cavitation and vibration and
may lead to severe pump damage.
To avoid these above problems, the forebay design should achieve and maintain the
following conditions:
• Uniform distribution of flow entering the forebay
• Minimal circulating flows in the forebay
• Filled zones of separation
• Minimal significant fluid rotation
The following design standards provide an initial design basis. Note that these stan-
dards are subject to variation with individual applications. Hydraulic model testing
will physically analyze the preliminary design and may suggest structural modifica-
tions toward the development of the final design.
2242 Forebay Design
General
Forebay design is based on the Hydraulic Institute Standards for sump design.
Continuing research on rectangular, free surface wet pit sumps with 3000 to
300,000 GPM capacities has yielded guidelines in pump position and approach
distance. All recommended distances are functions of the rated pump capacity at
design head.
As pump capacities exceed 300,000 GPM, however, the casing wall thickness (and
rigidity of support) increases disproportionally with the hydrodynamic loading on
the pump. Consequently, large capacity pumps are more prone to vibration and
demand better forebay design than smaller pumps. Using more stringent acceptance
criteria to measure “satisfactory” performance, the British Hydromechanics
Research Association has developed recommended dimensions based on the bell
diameter of large pumps.
The following sections contain general forebay design guidelines according to
pump type (i.e., horizontal or vertical pumps) and suggested forebay dimensions
according to pump capacity (i.e., 3000 to 300,000 GPM or pumps larger than
300,000 GPM).
Guidelines for Horizontal and Vertical Pumps
The following general guidelines are applicable to forebays with capacities
exceeding 3000 GPM and either horizontal or vertical pumps.
1. Ideally, a straight channel approaching the pump suction point(s) will deliver
uniform flow to the pump(s). Avoid any obstructions and/or turns that will
18. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-18 Chevron Corporation
cause abrupt changes in flow direction; e.g., sharp corners and rapidly
diverging passages may induce eddy currents and vortices.
2. Unavoidable obstructions such as columns and cross braces should be stream-
lined to reduce the trail of alternating vortices; these vortices form in the wake
of the obstructions as water flows past.
3. Maximum velocity of the flow approaching the pump(s) should be 1.0 foot per
second. Straightening vanes and/or a longer forebay length may reduce
velocities; if properly located near the mouth of the forebay inlet, trash screens
may also function as straightening vanes.
4. A longer forebay length may also be necessary to dissipate the kinetic energy
associated with steeply sloped floors, weirs, and steps, and therefore prevent
aeration.
5. “Dead pockets” of the forebay which contain stagnant water (e.g., corners
behind the suction point) may be eliminated via simple fillets or complex form-
work.
6. The inlet to the forebay should be below the normal operating water level to
avoid aeration.
7. In multiple-pump installations, water should not flow past one pump suction
point to reach another; i.e., pumps should not be placed in line with the flow of
water. To maintain even flow distribution, the water stream entering the
forebay should be normal to the line of pumps and along the line of symmetry.
8. For suction bells that must be placed in line of flow, an open front cell around
each intake may induce a more uniform flow into the pumps. Cells may be
unnecessary if both the longitudinal distance between intakes and the ratio of
forebay to pump size are quite large.
9. In multiple pump installations, rounded or “ogived” separating walls may be
beneficial if pumps operate simultaneously. Otherwise, separating walls should
be avoided.
10. To avoid uneven flow distribution in multiple-pump installations, pumps
should not be placed around the edge of the forebay.
11. To avoid upstream flooding, forebay volume should be sized to accommodate
the maximum design flow during pump operation. When constant-speed
pumps are used, volume must also be adequate to prevent short cycling (rapid
“on-off” operation) of the pumps.
12. Double screens should be placed ahead of the suction of the cooling water
pumps, particularly in new installations to screen out foreign materials.
Screens should be removable, while in service, for cleaning.
Guidelines for Horizontal Pumps Only
The following general guidelines are applicable to forebays with horizontal pumps
at capacities in excess of 3000 GPM; these standards should be used in conjunction
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with the information of the preceding section. Refer to Standard Drawing GB-
Q99594 for layout and piping details for horizontal pump suction lines.
1. Submergence for net positive suction head and minimal vortexing should be
according to pump manufacturer’s recommendations. On average, minimum
submergence of the suction intake is as follows:
a. Two line diameters when the intake is located in the forebay floor
b. One line diameter when the intake passes through the forebay wall
2. Vortex prevention plates just below the water surface may also be necessary to
prevent vortexing.
3. To mitigate any upstream flow disturbances, the minimum length of the suction
line should be ten line diameters.
4. An expansion joint and pipe anchor may be installed between the forebay wall
and pump to prevent overloading of the pump case.
5. Under suction lift conditions, suction piping should maintain an upward slope
to the pump; this slope helps prevent air entrainment and cavitation.
6. Under flooded suction conditions, the following conditions should be main-
tained:
a. Suction piping should be level or maintain a gradual downward slope to
the pump; the piping should not extend below the pump suction flange.
b. Diameter of the intake mouth should not be smaller than the diameter of
the suction piping.
c. A gate valve should be installed in the suction piping between the forebay
wall and expansion joints. The pump may then be “disconnected” from the
forebay during inspection and maintenance.
Guidelines for Vertical Pumps Only
The following general guidelines are applicable to forebays with vertical pumps at
capacities exceeding 3000 GPM; these standards should be used in conjunction
with the guidelines above for both horizontal and vertical pumps.
1. Submergence for net positive suction head and minimal vortexing should be
according to pump manufacturer’s recommendations. Typically, minimum
submergence is two times the suction bell diameter.
2. Necessary changes in floor elevation should occur at least three suction bell
diameters upstream of the pump column(s).
3. In multiple pump installations where pumps must be placed in line of flow,
turning vanes under each suction bell may deflect the flow upward and directly
into the pump. Vanes may be unnecessary if both the longitudinal distance
between intakes and the ratio of forebay to pump size are quite large.
20. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-20 Chevron Corporation
4. In multiple pump installations where flow distribution is skewed and pumps do
not operate simultaneously, flow splitters may redirect the flow to the suction
bells. Flow splitter lengths should be greater than four bell diameters.
Recommended Dimensions: 3000 to 300,000 GPM Capacity
The recommended forebay dimensions and layouts as shown in Figures 2200-6
through 2200-8 are applicable to facilities with either horizontal or vertical pumps
in the 3000 to 300,000 GPM capacity range (see also Standard Drawing GB-
Q99594). All dimensions are based on the rated capacity of each pump at design
head.
Dimension C is the distance between the bottom lip of suction bell and the forebay
floor. It is an average value subject to changes suggested by the pump manufacturer.
Dimension B is the recommended maximum distance between the centerline of the
suction bell and the forebay back wall. If actual Dimension B exceeds the
suggested length for structural or mechanical reasons, a “false” back wall may be
installed.
Dimension S is the recommended minimum center-to-center distance between
suction bells. In single pump installations, it is the minimum forebay width.
Dimension H is the suggested “normal low water level.” It is not the minimum
submergence required to prevent vortexing; submergence is normally defined as the
quantity H minus C.
Dimension Y is the minimum distance between the bell centerline and the first
upstream obstruction inside the forebay. For most bell designs, Dimension Y is
approximately three bell diameters.
Dimension A is the minimum overall forebay length when the average flow
velocity in the forebay is less than 2.0 feet per second.
Recommended Dimensions: Pumps Larger Than 300,000 GPM
The recommended forebay dimensions and layouts as shown in Figures 2200-9
through 2200-11 are applicable to facilities with either horizontal or vertical pumps
in the 300,000 GPM-plus capacity range. Dimensions are based on the intake or
suction bell diameter; unless noted otherwise, dimension symbols are identical to
those previously noted.
Dimension D is the diameter of the pump intake or suction bell.
Dimension X is the recommended distance between the edge of the bell and the
back forebay wall.
Dimension d is the diameter of the suction line or pump column.
21. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
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Fig. 2200-6 Sump Dimensions vs. Flow, 3000 to 300,000 GPM Capacity (Courtesy of the Hydraulic Institute)
Fig. 2200-7 Elevation of Basic Forebay Design, 3000 to 300,000 GPM Capacity (Courtesy of the Hydraulic Institute)
22. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-22 Chevron Corporation
2243 Hydraulic Model Testing
Because the hydraulic problems associated with forebay design are functions of
many variables, analysis of expected flow conditions is difficult. Unfortunately,
outside circumstances often force the designer to deviate from the design stan-
dards—and expected resulting flow conditions—described herein. On these occa-
sions, scaled hydraulic model testing may be the best method to analyze the
preliminary design.
In-situ simulation, while another possible alternative, is usually impractical. A
scaled model is more efficient because the system geometry can be quickly and
easily modified. The forebay size may be adjusted, various screen blockages
modeled, and instrumentation located in all areas of interest to measure momentum,
velocity distribution, and velocity changes at obstructions. Model forebay walls are
usually constructed of Plexiglas so that modelers and engineers may observe flow
patterns throughout the model.
The model should encompass all forebay components likely to influence the flow
entering the pump(s). Model boundaries should be located in areas where flow
pattern control has minimal boundary effects on the system. Models normally use
either equal Froude numbers or velocities; no significant scale effects occur in 1:2
and 1:4 models.
When conducted by an independent laboratory or the pump manufacturer, hydraulic
models are relatively inexpensive, reliable tools to analyze the hydraulic perfor-
mance of a preliminary design. Modifications suggested by models may also result
in substantial savings in later forebay construction, operation, and maintenance.
Since 1986, hydraulic models have been used to analyze the Richmond Refinery’s
Fig. 2200-8 Plan of Basic Forebay Design, 3000 to 300,000 GPM Capacity (Courtesy of the Hydraulic Institute)
23. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
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Fig. 2200-9 Elevation of Basic Forebay Designs, Pumps Larger than 300,000 GPM (From Hydraulic Design of Pump
Sumps and Intakes by Prosser. 1980 by the Construction Industry Research & Information Assn.,
London. Used with permission.)
24. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
December 1989 2200-24 Chevron Corporation
Fig. 2200-10 Plan of Basic Forebay Design, in Plane of Uniform Flow Approaching the Pumps, 300,000 GPM - Plus
Capacity (From Hydraulic Design of Pump Sumps and Intakes by Prosser. 1980 by the Construction
Industry Research & Information Assn., London. Used with permission.)
Fig. 2200-11 Plan of Basic Forebay Design, 300,000 GPM - Plus Capacity (From Hydraulic Design of Pump Sumps and
Intakes by Prosser. 1980 by the Construction Industry Research & Information Assn., London. Used
with permission.)
25. Heat Exchanger and Cooling Tower Manual 2200 Cooling Tower Design Guidelines
Chevron Corporation 2200-25 December 1989
flow splitter box of the 1A and 2A Separators, pump station of the Deep Water
Outfall, and No. 13 Separator.
In addition to developing possible structural modifications to improve flow condi-
tions in preliminary forebay design, models may also be used to correct conditions
in existing forebays. These improvements, the usual basic recommendations of a
model, are:
Increase the “normal low water level”. Usually, to simultaneously increase the
“normal low water level” and accommodate the desired operating forebay volume,
the forebay must be deepened. This change may increase excavation and engi-
neering costs.
Install antivortex devices. Devices such as cones, splitters, grids, and extension
plates may prevent or reduce vortexing in the forebay. The devices shown in
Figures 2200-12 and 2200-13 should also be selected in consultation with the pump
manufacturer.
Reshape the approach flow. Modifications may occur in the existing piping that
supplies the forebay and/or the inlet to the forebay.
2244 Standard Drawings
The following standard drawing is included in the Standard Drawings and Forms
section of this manual.
• GB-Q99594 Piping and Screen Details, Suction Pit for Cooling Tower Basin.
2245 References
1. Hydraulic Institute Standards for Centrifugal, Rotary & Reciprocating Pumps,
14th Edition, Hydraulic Institute, 1983.
2. Nystrom, James B., et al., “Modeling Flow Characteristics of Reactor Sumps,”
Journal of the Energy Division, ASCE, Vol. 108, No. EY3, November 1982.
3. Padmanabhan, M., and G. E. Hecker, “Scale Effects on Pump Sump Models,”
Journal of Hydraulic Engineering, ASCE, Vol. 110, No. 11, November 1984.
4. Prosser, M. J., The Hydraulic Design of Pump Sumps and Intakes, British
Hydromechanics Research Association/Construction Industry Research and
Information Association, 1980.
5. Sweeney, Charles E., et al., “Pump Sump Design Experience: Summary,”
Journal of the Hydraulics Division, ASCE, Vol. 108, No. HY3, March 1982.
26. 2200 Cooling Tower Design Guidelines Heat Exchanger and Cooling Tower Manual
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Fig. 2200-12 Modifications to Intake Design to Reduce Vortices (From Hydraulic Design of Pump Sumps and Intakes
by Prosser. 1980 by the Construction Industry Research & Information Assn., London. Used with
permission.)
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Fig. 2200-13 Other Modifications to Intake Design to Reduce Vortices (From Hydraulic Design of Pump Sumps and
Intakes by Prosser. 1980 by the Construction Industry Research & Information Assn., London. Used
with permission.)