Some interesting content about A-Frame condensers. Condensers can be applied in several processes like District Heating, Combined Heat & Power and Combined Cycle.
Some nice content for engineering freaks and people interested in the processes in which this special heat exchangers are used (industrial ventilation, gas transport & storage & extraction, rendering, diesel power, cooling and compression).
This document describes the Otto and Diesel cycles used in heat engines. The Otto cycle consists of four processes: isentropic compression, isochoric heat addition, isentropic expansion, and isochoric heat rejection. The Diesel cycle also consists of four processes: isentropic compression, isochoric heat addition, isentropic expansion, and isochoric heat rejection. Both cycles involve compressing air, adding heat, expanding the air to produce work, and rejecting heat. The key difference is that the Otto cycle adds heat at constant volume while the Diesel cycle adds heat at constant pressure. The document also provides details on the thermodynamics and mechanics of each process in the two cycles.
1) The Brayton cycle models the ideal thermodynamic cycle of a gas turbine engine. It consists of four processes: isentropic compression, constant-pressure heat addition, isentropic expansion, and constant-pressure heat rejection.
2) The thermal efficiency of an ideal Brayton cycle depends on the pressure ratio and specific heat ratio of the working fluid. Efficiency increases with higher pressure ratios.
3) Actual gas turbine cycles incorporate modifications like regeneration, which uses a heat exchanger to capture heat from the exhaust and transfer it to the compressed air, improving efficiency. Intercooling and reheating can also improve efficiency when used with regeneration.
Thermodynamic Cycles for CI engines
- Early CI engines injected fuel at top dead center, resulting in combustion during the expansion stroke. Modern engines inject fuel before top dead center, around 20 degrees.
- The combustion process in early CI engines approximates a constant pressure heat addition process, known as the Diesel cycle. Modern CI engines' combustion approximates a combination of constant volume and constant pressure processes, known as the Dual cycle.
- The air-standard Diesel cycle consists of four processes: isentropic compression, constant pressure heat addition, isentropic expansion, and constant volume heat rejection. Its thermal efficiency is lower than the Otto cycle for the same compression ratio due to the later fuel injection
This document presents information about a dual combustion engine. It was presented to Sir Qazi Shehzad by five students. The document defines a dual combustion engine as a four-stroke internal combustion engine where combustion occurs in two parts, first at constant pressure and then at constant volume. This makes it more efficient than a diesel engine. It also describes the key parts of the engine, the combustion cycle process, an equation for calculating its thermal efficiency, and its applications in vehicles, generators, and potentially future energy systems.
The Otto cycle is a 4-stroke combustion cycle used in gasoline engines. It was invented by Nikolaus Otto in 1876 and is made up of four processes: 1) Intake of fuel and air mixture, 2) Compression of the mixture, 3) Power or combustion where the mixture is ignited, and 4) Exhaust of combustion byproducts. The Otto cycle remains the basis for most modern car engines and was a major innovation that enabled the development of gasoline vehicles.
Some nice content for engineering freaks and people interested in the processes in which this special heat exchangers are used (industrial ventilation, gas transport & storage & extraction, rendering, diesel power, cooling and compression).
This document describes the Otto and Diesel cycles used in heat engines. The Otto cycle consists of four processes: isentropic compression, isochoric heat addition, isentropic expansion, and isochoric heat rejection. The Diesel cycle also consists of four processes: isentropic compression, isochoric heat addition, isentropic expansion, and isochoric heat rejection. Both cycles involve compressing air, adding heat, expanding the air to produce work, and rejecting heat. The key difference is that the Otto cycle adds heat at constant volume while the Diesel cycle adds heat at constant pressure. The document also provides details on the thermodynamics and mechanics of each process in the two cycles.
1) The Brayton cycle models the ideal thermodynamic cycle of a gas turbine engine. It consists of four processes: isentropic compression, constant-pressure heat addition, isentropic expansion, and constant-pressure heat rejection.
2) The thermal efficiency of an ideal Brayton cycle depends on the pressure ratio and specific heat ratio of the working fluid. Efficiency increases with higher pressure ratios.
3) Actual gas turbine cycles incorporate modifications like regeneration, which uses a heat exchanger to capture heat from the exhaust and transfer it to the compressed air, improving efficiency. Intercooling and reheating can also improve efficiency when used with regeneration.
Thermodynamic Cycles for CI engines
- Early CI engines injected fuel at top dead center, resulting in combustion during the expansion stroke. Modern engines inject fuel before top dead center, around 20 degrees.
- The combustion process in early CI engines approximates a constant pressure heat addition process, known as the Diesel cycle. Modern CI engines' combustion approximates a combination of constant volume and constant pressure processes, known as the Dual cycle.
- The air-standard Diesel cycle consists of four processes: isentropic compression, constant pressure heat addition, isentropic expansion, and constant volume heat rejection. Its thermal efficiency is lower than the Otto cycle for the same compression ratio due to the later fuel injection
This document presents information about a dual combustion engine. It was presented to Sir Qazi Shehzad by five students. The document defines a dual combustion engine as a four-stroke internal combustion engine where combustion occurs in two parts, first at constant pressure and then at constant volume. This makes it more efficient than a diesel engine. It also describes the key parts of the engine, the combustion cycle process, an equation for calculating its thermal efficiency, and its applications in vehicles, generators, and potentially future energy systems.
The Otto cycle is a 4-stroke combustion cycle used in gasoline engines. It was invented by Nikolaus Otto in 1876 and is made up of four processes: 1) Intake of fuel and air mixture, 2) Compression of the mixture, 3) Power or combustion where the mixture is ignited, and 4) Exhaust of combustion byproducts. The Otto cycle remains the basis for most modern car engines and was a major innovation that enabled the development of gasoline vehicles.
The document summarizes key aspects of diesel engine cycles and their thermodynamics. It discusses:
1) The diesel engine cycle involves isentropic compression, constant pressure heat addition, isentropic expansion, and constant volume heat rejection. This is similar to but distinct from the Otto cycle used in gasoline engines.
2) The thermal efficiency of the diesel cycle depends on the compression ratio and cutoff ratio, with higher efficiencies achieved at higher compression ratios and cutoff ratios closer to 1.
3) Despite sometimes having lower compression ratios, diesel engines are typically more efficient than gasoline engines because they add less heat per cycle, allowing the engine to run at higher speeds to produce the same power output.
The document describes the dual combustion cycle used in diesel and hot spot ignition engines. The cycle consists of (i) adiabatic compression from 1-2, (ii) addition of heat at constant volume from 2-3, (iii) adiabatic expansion from 3-4, and (iv) rejection of heat at constant pressure from 4-1. This cycle allows heat to be added partly at constant volume and partly at constant pressure, providing more time for fuel combustion compared to other cycles due to the lagging characteristics of diesel fuel.
The document discusses the idealized air standard diesel cycle that is used to analyze internal combustion engine processes. It describes how the actual open cycle is approximated as a closed cycle by assuming exhaust gases are recycled. It also outlines how the combustion process is replaced with constant pressure heat addition and other actual processes are approximated using ideal processes like constant pressure and isentropic. Finally, it provides the thermodynamic analysis of the six processes that make up the air standard diesel cycle and gives the equation to calculate the cycle's thermal efficiency.
This document provides an overview of mechanical engineering elements, including thermal prime movers, heat engines, heat engine cycles, and the Otto and Diesel cycles. It defines a heat engine as a device that absorbs heat and uses it to do useful work in a cycle. The Otto cycle uses combustion and constant volume processes, while the Diesel cycle uses constant pressure combustion. Key aspects of both cycles like their stages and efficiencies are described.
This document summarizes different types of power cycles used in gas engines. It describes gas cycles where the working fluid remains in gas phase throughout, and vapor cycles where it exists in both gas and liquid phases. The main gas cycles discussed are Carnot, Otto, Diesel, Dual, and Brayton cycles. Carnot cycle acts as an ideal benchmark, while Otto cycle models spark ignition engines, Diesel cycle models compression ignition engines, and Brayton cycle models jet and turboprop engines.
The document summarizes the Otto cycle and Diesel cycle, which are two common thermodynamic cycles used in internal combustion engines.
The Otto cycle consists of four processes: (1) isentropic compression, (2) constant volume heat addition, (3) isentropic expansion, (4) constant volume heat rejection. The thermal efficiency of an Otto cycle engine increases with compression ratio.
The Diesel cycle differs from the Otto cycle in that the combustion process (2-3) occurs at constant pressure rather than constant volume. As a result, Diesel cycle engines can operate at higher compression ratios than Otto cycle engines, giving them a higher overall thermal efficiency.
The document summarizes the classification and operation of internal combustion engines. It discusses two main types: four-stroke and two-stroke engines. Four-stroke engines involve intake, compression, power, and exhaust strokes in a repeating cycle, with valves and spark plugs controlling air and fuel flow. Two-stroke engines complete the power cycle in two strokes by using ports and crankcase compression instead of valves.
The document discusses intake and exhaust components for a vehicle. It includes:
- Service specifications and special tools for tasks like oxygen sensor removal
- Removal and installation steps for components like the air cleaner, intake manifold, exhaust manifold, and exhaust pipe/muffler
- Inspection procedures for parts such as checking for distortion on manifold surfaces
The document provides detailed removal and installation instructions, specifications, and points to note for servicing intake and exhaust systems.
This document summarizes four common gas power cycles: the Carnot, Otto, Diesel, and Brayton cycles. It describes the processes that occur in each cycle on P-V and T-S diagrams. The Carnot cycle consists of two isothermal and two isentropic processes. The Otto cycle has two isentropic and two isochoric (constant volume) processes. The Diesel cycle replaces one isochoric process with a constant pressure process. The Brayton cycle uses an open system analysis since the processes occur across a control volume. The document also provides equations to calculate the thermal efficiency of each cycle.
The dual cycle is an important part of I mechanical engineering.
here I have to try to derive some of the rules and important parts.
such as,
1.History
2.Comparison Between Otto, Diesel and Dual Cycle
3.Dual Combustion Engine
4.Characteristics
5.Parts Of Engine
6.Stroke
7.Sequence of Operations
8.Expression For Efficiency
9.Applications
10.Automobile
11.Generators/Aircrafts
12.Marine Engines
I hope this will help you to get all your required information plz like it and share it.
Connect with me on :
Youtube: Harshal Bhatt
Instagram: harshalbhatt_official
Twitter: HarshalBhatt318
Snapchat: harshalbhatt31
Success Story (1) World Largest Urea and NH3 plantSang Wai
NEW JCM received an order from one of the largest urea and ammonia plants for syngas compressors, ammonia refrigeration compressors, CO2 compressors, and air process compressors with mechanical drive steam turbines. All compressors and turbines were delivered on time. NEW JCM is the only Chinese manufacturer that can design, manufacture, and perform required tests for these products in a single factory.
The document summarizes several thermodynamic cycles including the Otto, Diesel, Carnot, refrigeration, and Brayton cycles. For each cycle, it outlines the key processes and applications. The Otto cycle involves two isentropic and two constant volume processes and is used in spark ignition engines. The Diesel cycle uses constant pressure heat addition and has a higher efficiency than the Otto cycle. The Carnot cycle involves reversible, isothermal and adiabatic processes and sets the maximum possible efficiency. The refrigeration cycle uses vapor compression to transfer heat between regions. The Brayton cycle consists of adiabatic compression and expansion with isobaric heat transfer and is commonly used in gas turbine engines.
The document describes the components and operation of a simple steam engine. It has a cylinder with a piston that is attached to a piston rod. The piston rod is connected to a crosshead that converts the linear motion of the piston into rotational motion via a connecting rod and crank. Live steam enters the cylinder through a slide valve to push the piston. The slide valve then directs exhaust steam out of the cylinder. The engine's actual operation differs from the theoretical due to factors like gradual valve timing, non-ideal expansion, and condensation/reevaporation of steam in the cylinder.
The document presents information on the Carnot cycle, a theoretical thermodynamic cycle proposed by Sadi Carnot in 1824. The Carnot cycle consists of four reversible processes involving two isothermal and two adiabatic steps using a perfect gas as a working substance between a heat source and heat sink. The efficiency of the Carnot cycle depends only on the temperature range and provides the maximum possible efficiency for converting heat into work in a thermodynamic cycle. However, the Carnot cycle is impossible to implement in practice due to assumptions of frictionless, infinitely slow isothermal processes and infinitely fast adiabatic processes.
Thermodynamic cycles are used to convert heat into work. The key cycles discussed are:
- Carnot cycle, which establishes the theoretical maximum efficiency possible.
- Rankine cycle, which uses steam to power turbines and is used in fossil fuel, nuclear, and other power plants.
- Brayton cycle, which is used in gas turbine engines with no phase change of the working fluid.
- Combined cycle, which uses exhaust from the Brayton cycle to power a Rankine cycle for higher overall efficiency.
Combustion rates and temperatures are limited by mixing, heating, compression rates, and material properties. Chemical kinetics also determine how quickly a fuel can fully oxidize to release its energy. Carbon
The document provides an introduction to internal combustion engines. It discusses the basic differences between internal and external combustion engines and classifications of internal combustion engines based on fuel, cycle of operation, and combustion process. It then describes the basic parts and working principles of 4-stroke petrol and diesel engines as well as 2-stroke petrol engines. Key differences between petrol and diesel engines are also highlighted. The document concludes by defining common terminology used in internal combustion engines.
This document contains a flow sheet for the production of phthalic anhydride from the oxidation of o-xylene. It includes a key for the codes used to identify 29 pieces of equipment in the process. The equipment includes storage tanks, conveyor belts, packing equipment, bins, screw conveyors, spray towers, pumps, accumulators, condensers, reboilers, distillation towers, reactors, heat exchangers, blowers, air filters and vaporizers.
The document provides information on internal combustion engines, including:
- IC engines convert chemical energy from fuels like gasoline into mechanical work. They are used in vehicles, generators, and other machinery.
- The basic components of IC engines are cylinders, pistons, inlet/exhaust valves. Pistons move between top and bottom dead centers.
- IC engines are classified as either spark-ignition (gasoline) or compression-ignition (diesel) based on how combustion is initiated in the cylinder.
The document then discusses air standard cycles that model idealized versions of engine cycles, including the Otto cycle for gasoline engines and Diesel cycle for diesel engines. It provides analysis of the cycles
A condenser is a heat exchanger that transfers vapors into a liquid state by removing latent heat with a coolant like water. This document provides design calculations for an 8 unit shell and tube condenser with 1030 tubes that uses cold water as the coolant to condense steam at a rate of 8060 kg/hr and 4343 kW of heat duty. Key specifications are provided, like a calculated overall heat transfer coefficient of 1100.97 W/m2C and pressure drops of 0.59 psi for the tube side and 0.109 psi for the shell side. References on condenser design are also listed.
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
The document summarizes key aspects of diesel engine cycles and their thermodynamics. It discusses:
1) The diesel engine cycle involves isentropic compression, constant pressure heat addition, isentropic expansion, and constant volume heat rejection. This is similar to but distinct from the Otto cycle used in gasoline engines.
2) The thermal efficiency of the diesel cycle depends on the compression ratio and cutoff ratio, with higher efficiencies achieved at higher compression ratios and cutoff ratios closer to 1.
3) Despite sometimes having lower compression ratios, diesel engines are typically more efficient than gasoline engines because they add less heat per cycle, allowing the engine to run at higher speeds to produce the same power output.
The document describes the dual combustion cycle used in diesel and hot spot ignition engines. The cycle consists of (i) adiabatic compression from 1-2, (ii) addition of heat at constant volume from 2-3, (iii) adiabatic expansion from 3-4, and (iv) rejection of heat at constant pressure from 4-1. This cycle allows heat to be added partly at constant volume and partly at constant pressure, providing more time for fuel combustion compared to other cycles due to the lagging characteristics of diesel fuel.
The document discusses the idealized air standard diesel cycle that is used to analyze internal combustion engine processes. It describes how the actual open cycle is approximated as a closed cycle by assuming exhaust gases are recycled. It also outlines how the combustion process is replaced with constant pressure heat addition and other actual processes are approximated using ideal processes like constant pressure and isentropic. Finally, it provides the thermodynamic analysis of the six processes that make up the air standard diesel cycle and gives the equation to calculate the cycle's thermal efficiency.
This document provides an overview of mechanical engineering elements, including thermal prime movers, heat engines, heat engine cycles, and the Otto and Diesel cycles. It defines a heat engine as a device that absorbs heat and uses it to do useful work in a cycle. The Otto cycle uses combustion and constant volume processes, while the Diesel cycle uses constant pressure combustion. Key aspects of both cycles like their stages and efficiencies are described.
This document summarizes different types of power cycles used in gas engines. It describes gas cycles where the working fluid remains in gas phase throughout, and vapor cycles where it exists in both gas and liquid phases. The main gas cycles discussed are Carnot, Otto, Diesel, Dual, and Brayton cycles. Carnot cycle acts as an ideal benchmark, while Otto cycle models spark ignition engines, Diesel cycle models compression ignition engines, and Brayton cycle models jet and turboprop engines.
The document summarizes the Otto cycle and Diesel cycle, which are two common thermodynamic cycles used in internal combustion engines.
The Otto cycle consists of four processes: (1) isentropic compression, (2) constant volume heat addition, (3) isentropic expansion, (4) constant volume heat rejection. The thermal efficiency of an Otto cycle engine increases with compression ratio.
The Diesel cycle differs from the Otto cycle in that the combustion process (2-3) occurs at constant pressure rather than constant volume. As a result, Diesel cycle engines can operate at higher compression ratios than Otto cycle engines, giving them a higher overall thermal efficiency.
The document summarizes the classification and operation of internal combustion engines. It discusses two main types: four-stroke and two-stroke engines. Four-stroke engines involve intake, compression, power, and exhaust strokes in a repeating cycle, with valves and spark plugs controlling air and fuel flow. Two-stroke engines complete the power cycle in two strokes by using ports and crankcase compression instead of valves.
The document discusses intake and exhaust components for a vehicle. It includes:
- Service specifications and special tools for tasks like oxygen sensor removal
- Removal and installation steps for components like the air cleaner, intake manifold, exhaust manifold, and exhaust pipe/muffler
- Inspection procedures for parts such as checking for distortion on manifold surfaces
The document provides detailed removal and installation instructions, specifications, and points to note for servicing intake and exhaust systems.
This document summarizes four common gas power cycles: the Carnot, Otto, Diesel, and Brayton cycles. It describes the processes that occur in each cycle on P-V and T-S diagrams. The Carnot cycle consists of two isothermal and two isentropic processes. The Otto cycle has two isentropic and two isochoric (constant volume) processes. The Diesel cycle replaces one isochoric process with a constant pressure process. The Brayton cycle uses an open system analysis since the processes occur across a control volume. The document also provides equations to calculate the thermal efficiency of each cycle.
The dual cycle is an important part of I mechanical engineering.
here I have to try to derive some of the rules and important parts.
such as,
1.History
2.Comparison Between Otto, Diesel and Dual Cycle
3.Dual Combustion Engine
4.Characteristics
5.Parts Of Engine
6.Stroke
7.Sequence of Operations
8.Expression For Efficiency
9.Applications
10.Automobile
11.Generators/Aircrafts
12.Marine Engines
I hope this will help you to get all your required information plz like it and share it.
Connect with me on :
Youtube: Harshal Bhatt
Instagram: harshalbhatt_official
Twitter: HarshalBhatt318
Snapchat: harshalbhatt31
Success Story (1) World Largest Urea and NH3 plantSang Wai
NEW JCM received an order from one of the largest urea and ammonia plants for syngas compressors, ammonia refrigeration compressors, CO2 compressors, and air process compressors with mechanical drive steam turbines. All compressors and turbines were delivered on time. NEW JCM is the only Chinese manufacturer that can design, manufacture, and perform required tests for these products in a single factory.
The document summarizes several thermodynamic cycles including the Otto, Diesel, Carnot, refrigeration, and Brayton cycles. For each cycle, it outlines the key processes and applications. The Otto cycle involves two isentropic and two constant volume processes and is used in spark ignition engines. The Diesel cycle uses constant pressure heat addition and has a higher efficiency than the Otto cycle. The Carnot cycle involves reversible, isothermal and adiabatic processes and sets the maximum possible efficiency. The refrigeration cycle uses vapor compression to transfer heat between regions. The Brayton cycle consists of adiabatic compression and expansion with isobaric heat transfer and is commonly used in gas turbine engines.
The document describes the components and operation of a simple steam engine. It has a cylinder with a piston that is attached to a piston rod. The piston rod is connected to a crosshead that converts the linear motion of the piston into rotational motion via a connecting rod and crank. Live steam enters the cylinder through a slide valve to push the piston. The slide valve then directs exhaust steam out of the cylinder. The engine's actual operation differs from the theoretical due to factors like gradual valve timing, non-ideal expansion, and condensation/reevaporation of steam in the cylinder.
The document presents information on the Carnot cycle, a theoretical thermodynamic cycle proposed by Sadi Carnot in 1824. The Carnot cycle consists of four reversible processes involving two isothermal and two adiabatic steps using a perfect gas as a working substance between a heat source and heat sink. The efficiency of the Carnot cycle depends only on the temperature range and provides the maximum possible efficiency for converting heat into work in a thermodynamic cycle. However, the Carnot cycle is impossible to implement in practice due to assumptions of frictionless, infinitely slow isothermal processes and infinitely fast adiabatic processes.
Thermodynamic cycles are used to convert heat into work. The key cycles discussed are:
- Carnot cycle, which establishes the theoretical maximum efficiency possible.
- Rankine cycle, which uses steam to power turbines and is used in fossil fuel, nuclear, and other power plants.
- Brayton cycle, which is used in gas turbine engines with no phase change of the working fluid.
- Combined cycle, which uses exhaust from the Brayton cycle to power a Rankine cycle for higher overall efficiency.
Combustion rates and temperatures are limited by mixing, heating, compression rates, and material properties. Chemical kinetics also determine how quickly a fuel can fully oxidize to release its energy. Carbon
The document provides an introduction to internal combustion engines. It discusses the basic differences between internal and external combustion engines and classifications of internal combustion engines based on fuel, cycle of operation, and combustion process. It then describes the basic parts and working principles of 4-stroke petrol and diesel engines as well as 2-stroke petrol engines. Key differences between petrol and diesel engines are also highlighted. The document concludes by defining common terminology used in internal combustion engines.
This document contains a flow sheet for the production of phthalic anhydride from the oxidation of o-xylene. It includes a key for the codes used to identify 29 pieces of equipment in the process. The equipment includes storage tanks, conveyor belts, packing equipment, bins, screw conveyors, spray towers, pumps, accumulators, condensers, reboilers, distillation towers, reactors, heat exchangers, blowers, air filters and vaporizers.
The document provides information on internal combustion engines, including:
- IC engines convert chemical energy from fuels like gasoline into mechanical work. They are used in vehicles, generators, and other machinery.
- The basic components of IC engines are cylinders, pistons, inlet/exhaust valves. Pistons move between top and bottom dead centers.
- IC engines are classified as either spark-ignition (gasoline) or compression-ignition (diesel) based on how combustion is initiated in the cylinder.
The document then discusses air standard cycles that model idealized versions of engine cycles, including the Otto cycle for gasoline engines and Diesel cycle for diesel engines. It provides analysis of the cycles
A condenser is a heat exchanger that transfers vapors into a liquid state by removing latent heat with a coolant like water. This document provides design calculations for an 8 unit shell and tube condenser with 1030 tubes that uses cold water as the coolant to condense steam at a rate of 8060 kg/hr and 4343 kW of heat duty. Key specifications are provided, like a calculated overall heat transfer coefficient of 1100.97 W/m2C and pressure drops of 0.59 psi for the tube side and 0.109 psi for the shell side. References on condenser design are also listed.
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
STUDY OF CONDENSER AND ITS DIFFERENT TYPESAziz Rehman
This study examines different types of condensers used in refrigerants. It discusses air cooled and water cooled condensers. Air cooled condensers can use natural or forced convection, while water cooled condensers include tube-in-tube, shell-and-coil, and shell-and-tube designs. The study tests different materials for condensers, finding that copper has the highest thermal conductivity and best heat transfer, followed by aluminum and steel. The objective is to select the best material for a condenser by considering factors like thermal conductivity and heat transfer performance.
This document discusses steam condensers and their types. It defines a condenser as a device that condenses steam to water using cooling water. There are two main types - jet condensers and surface condensers. Jet condensers mix steam and cooling water directly, while surface condensers separate them with a heat transfer wall. The document classifies condensers in various ways and describes the functions, elements, advantages and disadvantages of different condenser types. It also discusses vacuum creation, sources of air leaks, and the effect of condenser pressure on thermal efficiency.
A condenser is a device that condenses steam into water by removing heat and lowering the pressure. It allows steam from a turbine to be condensed and reused as feedwater in a steam power plant. There are two main types: jet condensers where steam directly contacts cooling water, and surface condensers where they are separated. Surface condensers are more suitable for large plants since they can achieve higher vacuums and produce clean condensate that can be reused. Maintaining high vacuum through minimizing air leakage is important for thermal efficiency.
The document discusses vapour absorption refrigeration systems. It describes a simple vapour absorption system using ammonia and water, and a practical system. It defines the coefficient of performance (COP) of an ideal absorption system and lists properties desired in ideal refrigerants and absorbents. The document also discusses the domestic Electrolux refrigerator, which uses ammonia, hydrogen and water, and operates entirely through gravity flow without pumps. Key advantages of absorption systems over compression include having no moving parts and ability to operate on thermal energy alone.
Solar refrigeration uses solar energy to power refrigeration systems for food and medicine preservation and comfort cooling. There are three main types of solar refrigeration: photovoltaic operated vapor compression, solar mechanical vapor compression using a Rankine cycle, and absorption refrigeration. Absorption refrigeration replaces the compressor with a thermal compression system using ammonia as the working fluid and a generator powered by solar collectors to desorb the ammonia, providing refrigeration without large mechanical energy inputs. While solar refrigeration has benefits of being environmentally friendly and not relying on power grids, its high initial costs and low coefficient of performance currently limit widespread adoption.
Compression is a process that contains smart engineering. Absorption or compression refrigeration? Refrigerant condenser or evaporator? You choose. Feel free to have a look. We are ready to help you!
Industrial fans often play an important role in energy related processes. What about Centrifugal Fans ? They are used quite some processes Rendering, LNG Vaporisers, Food, Fertiliser, Cooling, Ammonia. Like to know more about these hi tech cracks? Have a look.
Air separation units: technology on the move!BRONSWERK
The document discusses air separation units which use cryogenic air separation to separate nitrogen, oxygen, and argon from atmospheric air. The process involves filtering air, increasing its pressure through compressor stages and heat exchangers to create liquid air, and then distilling the liquid in columns to separate the gases. The company supplies heat exchangers and coolers to evaporate and condense fluids at various stages of the air separation process. Their equipment is specially designed to withstand cold temperatures and prevent freezing.
An innovative story about coolers/condensers in the process of desulphurisation of crude oils. Nice content if you work or have interest in the oil refinery.
EQUIPMENT FOR EXTINGUISHER & CYLINDER MAINTENANCE AND TESTING / CLEAN AGENT H...marketingequipment
Company presentation featuring a wide a range of equipment for extinguisher and cylinder maintenance, service and testing. We produce units for CO2 transfer, powder extinguisher filling, cylinder maintenance and testing, clean agent filling and recovery, inert gas filling, refrigerant filling. Our product range is fully designed and produced at our headuarters in North-West Italy.
The document discusses condensers, which are devices that liquefy fluids or vapors. It describes different types of condensers like surface condensers, steam condensers, and A-frame condensers. The document also provides links to pages on Bronswerk's website about condenser applications in various industries like power plants, oil refineries, and pharmaceutical facilities. It invites the reader to learn more about Bronswerk's heat exchange solutions and encourages connecting on social media.
Heat Exchangers play an important role in many industrial processes like District Heating, Pulp & Paper, Oil Refinery & Extraction, Gas Extraction and Hydro Crackers. Enjoy reading.
Howden is a global leader in compressor technologies and expertise, with over 160 years of experience. They incorporate the original innovators of diaphragm, twin screw, and Roots technologies. Howden designs and manufactures all major compressor technologies, including reciprocating, centrifugal, screw, and Roots blowers. They provide customized compressor solutions and support for applications across industries such as oil and gas, petrochemical, chemical, power generation, and more.
The document discusses Howden, a global organization that brings together the innovators of major compressor technologies. It summarizes Howden's expertise across compressor technologies including reciprocating, screw, centrifugal, and Roots compressors. Howden can advise on and supply compressors for any application based on over 160 years of experience in compressor engineering.
Are you happy with your #energy #ROI? Custom made #engineering solutions can make the difference. Interested? Have a look at this content and feel free to contact us.
(https://www.indiamart.com/ksvalves) Owing to immense industry experience and knowledge, we have emerged as a renowned manufacturer, exporter and supplier of an assorted range of Industrial Valves, Strainer and PRV & PRDSH Station. These products are manufactured at our high-tech manufacturing unit in compliance with international quality standards using optimum quality components and advanced technology. Further, these products are known for smooth performance, rigid construction, corrosion resistance and longer service life.
Started to create milestones, we Sawant High Vac Industries Mumbai marked our presence in the year 2010 and operates in the manufacturing/servicing of Vacuum Pumps, Vacuum Pumps Accessories, Liquid Ring Vacuum Pump System, Cavity Pumps Slicer since 2 years. Our quality services/products have always won us many appreciations from our clients. Our spontaneous performance and confident approach in offering the excellent range of Vacuum Pumps, Vacuum Pumps Accessories, Liquid Ring Vacuum Pump System, Cavity Pumps that has made us to deepen our roots in the market. We Sawant High Vac Industries Mumbai breathe with the aim to satisfy our clients with our smart products/services. We are a unit of highly experienced professionals who all contribute best of their potentials to offer high efficiency.
Steam generators are quite essential in a lot of industrial processes. They can be used for example in Solar Power, Rendering, Fertilising, Diesel Power and Combined Cycle. Interested? Have a look.
Körting steam jet chilling plants use water as a refrigerant and provide environmentally-friendly operation with high operational safety and minimal maintenance needs. They utilize unused steam to power a jet vacuum ejector that cools liquid through flash evaporation without mechanical components. Applications include large chilling capacities over 1 MW for processes with excess steam. Multi-stage designs further reduce steam and water usage to lower costs.
Körting steam jet chilling plants use water as a refrigerant and provide environmentally-friendly operation with high operational safety and minimal maintenance needs. They utilize unused steam to power a jet vacuum ejector that cools liquid through flash evaporation without mechanical components. Applications include large chilling capacities over 1 MW for processes with excess steam. Multi-stage designs further reduce steam and water usage to lower costs.
Rastgar & Co introduces it specialisation in Air Compressors of all kinds, sales, service, spares, turnkey solutions, maintenance, air end refurbishment, at all industrial sites in Pakistan. Several CompAir, Gardner Denver products are handled.
Do you know the energy aspects of rendering? Have a look at the interesting processes behind the industry that processes carcasses and offal. Please contact us if you want to know more about the commercial opportunities for your company or organisation.
Bronswerk provides process design, thermal design, and mechanical design services to help clients optimize plant efficiency and recover waste heat. Their Radiax compressor can significantly reduce the size and energy usage of vapor recompression systems. Their Whizz-wheel fan uses curved blades to lower noise levels by 6-20 dB compared to conventional fans, reducing energy usage by 45-60% for the same airflow. Case studies show their technologies helped a client in Mexico debottleneck a gas compression module by 40% in space usage and 24% in energy, and helped a refinery in Germany reduce fan noise by 20 dB while lowering energy usage by 56%.
Afval heeft vaak nog energie potentieel. Bij de verbranding kan stoom opgewekt worden. Meer weten over de mogelijkheden van waste energy? Lees erover in deze presentatie inclusief een klanten case.
Geothermische energie meeliften met de energie van de aardeBRONSWERK
De aarde is een rijke bron van energie. Neem bijvoorbeeld aardwarmte. Maar weet u hoe u hiervan slim gebruik kan maken? Kent u de juiste technieken en processen? In deze presentatie is beschreven het winnen van geothermische energie en hoe wij een klant in Ijsland hebben geholpen met slimme engineering.
Stadsverwarming Laat Uw Buren Niet In De Kou Staan.BRONSWERK
Bij elektriciteitsproductie komt veel restwarmte vrij. Vaak is het onmogelijk om die restwarmte in de centrale zelf te gebruiken. Maar die restwarmte is prima geschikt om de bebouwde omgeving in de buurt te verwarmen. Meer weten hoe efficiency te verbeteren en milieu te sparen? U leest het in deze presentatie.
Bronswerk Heat Transfer Wereld Speler In Warmte WisselaarsBRONSWERK
Warmte wisselaars ontwerpen en bouwen een koud kunstje? Bronwerk draait er zijn hand niet voor om waar ook ter wereld.
Bron: artikel LASTECHNIEK Februari 2015 door Margriet Wennekes
Hete en onbenutte uitlaatgassen bieden een enorm energie potentieel binnen elektriciteitscentrales. Het rendement van deze centrales is flink te verhogen door de hoge temperatuur van de uitlaatgassen te benutten om stoom te maken. Lees meer over de efficiency van het gezamenlijk gebruik van stoom en gas inclusief een combined cycle case.
Warmte kracht is een bijzonder energie proces. Het voordeel is het benutten van restwarmte. Dit proces ook wel bekend als Combined Heat Power biedt veel potentieel tot energie besparing en verhoging van efficiency.
Laat u inspireren door deze slimme engineering content inclusief een interessante klanten case.
Bronswerk presentation Air Cooled Condensers Group 6th Annual Meeting.BRONSWERK
Bronswerk Heat Transfer is participant at the Air Cooled Condensers 6th Annual Meeting 22-25 September 2014 in San Diego.
Read about dynamic air cooled condenser solutions & Innovation in Process Equipment.
Do you know vessels? They often play an important role in energy management especially in the pharmaceutical industry. Have a look at these 'state-of-the-art' machines. If we can help you improve your energy ROI, let us know. We are eager to help you :-).
Research & development innovation radiax technologyBRONSWERK
Holidays are often a moment of looking back & looking forward. For example your performance regarding energy management. Berhaps we can help you with some small or big steps. Interested? Have a look and enjoy your holiday.
The document discusses the Klarex non-fouling heat exchanger, which prevents fouling from accumulating inside the tubes. It works by continuously circulating metallic anti-fouling particles with the fluid to prevent fouling from starting and to improve heat exchange. The particles are distributed uniformly through a multiple path system and their quantity can be adjusted. The Klarex exchanger remains clean indefinitely, requires no maintenance, and operates reliably for many years without interruption.
Engineering systems : sustainability rules.BRONSWERK
We like to share our knowledge about heat transfer with our clients and stakeholders. Engineering systems for example. We have a focus on sustainability. Working on the best possible performance is our driver. Like to know more? Have a look.
Heat exchange solutions require often outstanding engineering. Warm water or steam play an important role. Like to know more about heaters? Have a look at this content. If you have any questions or energy issues feel free to contact us. We help customers since 1940.
Bronswerk Heat Transfer is an engineering company focused on sustainable solutions. They develop energy efficient heat exchangers, cooling systems, condensers, and fans. Their innovations include a compact header design for shell and tube heat exchangers that uses less material, and a new Whizz-Wheel fan that is lighter, quieter, and more efficient than existing fans. Bronswerk offers customized solutions and services to address clients' heat transfer needs.
Did you know that in Europe we annually use more than fifty million tonnes of cardboard and paper? Berhaps you are wondering how much energy is used in the production of paper? Have a look at some interesting engineering content. Enjoy reading.
Engineering is key regarding safety of Pharmaceutical products. What kind of technology and processes are relevant? Have a look and feel free to contact us if you have any questions.
What is an RPA CoE? Session 2 – CoE RolesDianaGray10
In this session, we will review the players involved in the CoE and how each role impacts opportunities.
Topics covered:
• What roles are essential?
• What place in the automation journey does each role play?
Speaker:
Chris Bolin, Senior Intelligent Automation Architect Anika Systems
Dandelion Hashtable: beyond billion requests per second on a commodity serverAntonios Katsarakis
This slide deck presents DLHT, a concurrent in-memory hashtable. Despite efforts to optimize hashtables, that go as far as sacrificing core functionality, state-of-the-art designs still incur multiple memory accesses per request and block request processing in three cases. First, most hashtables block while waiting for data to be retrieved from memory. Second, open-addressing designs, which represent the current state-of-the-art, either cannot free index slots on deletes or must block all requests to do so. Third, index resizes block every request until all objects are copied to the new index. Defying folklore wisdom, DLHT forgoes open-addressing and adopts a fully-featured and memory-aware closed-addressing design based on bounded cache-line-chaining. This design offers lock-free index operations and deletes that free slots instantly, (2) completes most requests with a single memory access, (3) utilizes software prefetching to hide memory latencies, and (4) employs a novel non-blocking and parallel resizing. In a commodity server and a memory-resident workload, DLHT surpasses 1.6B requests per second and provides 3.5x (12x) the throughput of the state-of-the-art closed-addressing (open-addressing) resizable hashtable on Gets (Deletes).
"Frontline Battles with DDoS: Best practices and Lessons Learned", Igor IvaniukFwdays
At this talk we will discuss DDoS protection tools and best practices, discuss network architectures and what AWS has to offer. Also, we will look into one of the largest DDoS attacks on Ukrainian infrastructure that happened in February 2022. We'll see, what techniques helped to keep the web resources available for Ukrainians and how AWS improved DDoS protection for all customers based on Ukraine experience
LF Energy Webinar: Carbon Data Specifications: Mechanisms to Improve Data Acc...DanBrown980551
This LF Energy webinar took place June 20, 2024. It featured:
-Alex Thornton, LF Energy
-Hallie Cramer, Google
-Daniel Roesler, UtilityAPI
-Henry Richardson, WattTime
In response to the urgency and scale required to effectively address climate change, open source solutions offer significant potential for driving innovation and progress. Currently, there is a growing demand for standardization and interoperability in energy data and modeling. Open source standards and specifications within the energy sector can also alleviate challenges associated with data fragmentation, transparency, and accessibility. At the same time, it is crucial to consider privacy and security concerns throughout the development of open source platforms.
This webinar will delve into the motivations behind establishing LF Energy’s Carbon Data Specification Consortium. It will provide an overview of the draft specifications and the ongoing progress made by the respective working groups.
Three primary specifications will be discussed:
-Discovery and client registration, emphasizing transparent processes and secure and private access
-Customer data, centering around customer tariffs, bills, energy usage, and full consumption disclosure
-Power systems data, focusing on grid data, inclusive of transmission and distribution networks, generation, intergrid power flows, and market settlement data
AppSec PNW: Android and iOS Application Security with MobSFAjin Abraham
Mobile Security Framework - MobSF is a free and open source automated mobile application security testing environment designed to help security engineers, researchers, developers, and penetration testers to identify security vulnerabilities, malicious behaviours and privacy concerns in mobile applications using static and dynamic analysis. It supports all the popular mobile application binaries and source code formats built for Android and iOS devices. In addition to automated security assessment, it also offers an interactive testing environment to build and execute scenario based test/fuzz cases against the application.
This talk covers:
Using MobSF for static analysis of mobile applications.
Interactive dynamic security assessment of Android and iOS applications.
Solving Mobile app CTF challenges.
Reverse engineering and runtime analysis of Mobile malware.
How to shift left and integrate MobSF/mobsfscan SAST and DAST in your build pipeline.
QR Secure: A Hybrid Approach Using Machine Learning and Security Validation F...AlexanderRichford
QR Secure: A Hybrid Approach Using Machine Learning and Security Validation Functions to Prevent Interaction with Malicious QR Codes.
Aim of the Study: The goal of this research was to develop a robust hybrid approach for identifying malicious and insecure URLs derived from QR codes, ensuring safe interactions.
This is achieved through:
Machine Learning Model: Predicts the likelihood of a URL being malicious.
Security Validation Functions: Ensures the derived URL has a valid certificate and proper URL format.
This innovative blend of technology aims to enhance cybersecurity measures and protect users from potential threats hidden within QR codes 🖥 🔒
This study was my first introduction to using ML which has shown me the immense potential of ML in creating more secure digital environments!
AI in the Workplace Reskilling, Upskilling, and Future Work.pptxSunil Jagani
Discover how AI is transforming the workplace and learn strategies for reskilling and upskilling employees to stay ahead. This comprehensive guide covers the impact of AI on jobs, essential skills for the future, and successful case studies from industry leaders. Embrace AI-driven changes, foster continuous learning, and build a future-ready workforce.
Read More - https://bit.ly/3VKly70
Getting the Most Out of ScyllaDB Monitoring: ShareChat's TipsScyllaDB
ScyllaDB monitoring provides a lot of useful information. But sometimes it’s not easy to find the root of the problem if something is wrong or even estimate the remaining capacity by the load on the cluster. This talk shares our team's practical tips on: 1) How to find the root of the problem by metrics if ScyllaDB is slow 2) How to interpret the load and plan capacity for the future 3) Compaction strategies and how to choose the right one 4) Important metrics which aren’t available in the default monitoring setup.
"Choosing proper type of scaling", Olena SyrotaFwdays
Imagine an IoT processing system that is already quite mature and production-ready and for which client coverage is growing and scaling and performance aspects are life and death questions. The system has Redis, MongoDB, and stream processing based on ksqldb. In this talk, firstly, we will analyze scaling approaches and then select the proper ones for our system.
[OReilly Superstream] Occupy the Space: A grassroots guide to engineering (an...Jason Yip
The typical problem in product engineering is not bad strategy, so much as “no strategy”. This leads to confusion, lack of motivation, and incoherent action. The next time you look for a strategy and find an empty space, instead of waiting for it to be filled, I will show you how to fill it in yourself. If you’re wrong, it forces a correction. If you’re right, it helps create focus. I’ll share how I’ve approached this in the past, both what works and lessons for what didn’t work so well.
This talk will cover ScyllaDB Architecture from the cluster-level view and zoom in on data distribution and internal node architecture. In the process, we will learn the secret sauce used to get ScyllaDB's high availability and superior performance. We will also touch on the upcoming changes to ScyllaDB architecture, moving to strongly consistent metadata and tablets.
Northern Engraving | Modern Metal Trim, Nameplates and Appliance PanelsNorthern Engraving
What began over 115 years ago as a supplier of precision gauges to the automotive industry has evolved into being an industry leader in the manufacture of product branding, automotive cockpit trim and decorative appliance trim. Value-added services include in-house Design, Engineering, Program Management, Test Lab and Tool Shops.
GlobalLogic Java Community Webinar #18 “How to Improve Web Application Perfor...GlobalLogic Ukraine
Під час доповіді відповімо на питання, навіщо потрібно підвищувати продуктивність аплікації і які є найефективніші способи для цього. А також поговоримо про те, що таке кеш, які його види бувають та, основне — як знайти performance bottleneck?
Відео та деталі заходу: https://bit.ly/45tILxj
Session 1 - Intro to Robotic Process Automation.pdfUiPathCommunity
👉 Check out our full 'Africa Series - Automation Student Developers (EN)' page to register for the full program:
https://bit.ly/Automation_Student_Kickstart
In this session, we shall introduce you to the world of automation, the UiPath Platform, and guide you on how to install and setup UiPath Studio on your Windows PC.
📕 Detailed agenda:
What is RPA? Benefits of RPA?
RPA Applications
The UiPath End-to-End Automation Platform
UiPath Studio CE Installation and Setup
💻 Extra training through UiPath Academy:
Introduction to Automation
UiPath Business Automation Platform
Explore automation development with UiPath Studio
👉 Register here for our upcoming Session 2 on June 20: Introduction to UiPath Studio Fundamentals: https://community.uipath.com/events/details/uipath-lagos-presents-session-2-introduction-to-uipath-studio-fundamentals/
In our second session, we shall learn all about the main features and fundamentals of UiPath Studio that enable us to use the building blocks for any automation project.
📕 Detailed agenda:
Variables and Datatypes
Workflow Layouts
Arguments
Control Flows and Loops
Conditional Statements
💻 Extra training through UiPath Academy:
Variables, Constants, and Arguments in Studio
Control Flow in Studio
Northern Engraving | Nameplate Manufacturing Process - 2024Northern Engraving
Manufacturing custom quality metal nameplates and badges involves several standard operations. Processes include sheet prep, lithography, screening, coating, punch press and inspection. All decoration is completed in the flat sheet with adhesive and tooling operations following. The possibilities for creating unique durable nameplates are endless. How will you create your brand identity? We can help!
Must Know Postgres Extension for DBA and Developer during MigrationMydbops
Mydbops Opensource Database Meetup 16
Topic: Must-Know PostgreSQL Extensions for Developers and DBAs During Migration
Speaker: Deepak Mahto, Founder of DataCloudGaze Consulting
Date & Time: 8th June | 10 AM - 1 PM IST
Venue: Bangalore International Centre, Bangalore
Abstract: Discover how PostgreSQL extensions can be your secret weapon! This talk explores how key extensions enhance database capabilities and streamline the migration process for users moving from other relational databases like Oracle.
Key Takeaways:
* Learn about crucial extensions like oracle_fdw, pgtt, and pg_audit that ease migration complexities.
* Gain valuable strategies for implementing these extensions in PostgreSQL to achieve license freedom.
* Discover how these key extensions can empower both developers and DBAs during the migration process.
* Don't miss this chance to gain practical knowledge from an industry expert and stay updated on the latest open-source database trends.
Mydbops Managed Services specializes in taking the pain out of database management while optimizing performance. Since 2015, we have been providing top-notch support and assistance for the top three open-source databases: MySQL, MongoDB, and PostgreSQL.
Our team offers a wide range of services, including assistance, support, consulting, 24/7 operations, and expertise in all relevant technologies. We help organizations improve their database's performance, scalability, efficiency, and availability.
Contact us: info@mydbops.com
Visit: https://www.mydbops.com/
Follow us on LinkedIn: https://in.linkedin.com/company/mydbops
For more details and updates, please follow up the below links.
Meetup Page : https://www.meetup.com/mydbops-databa...
Twitter: https://twitter.com/mydbopsofficial
Blogs: https://www.mydbops.com/blog/
Facebook(Meta): https://www.facebook.com/mydbops/
Essentials of Automations: Exploring Attributes & Automation ParametersSafe Software
Building automations in FME Flow can save time, money, and help businesses scale by eliminating data silos and providing data to stakeholders in real-time. One essential component to orchestrating complex automations is the use of attributes & automation parameters (both formerly known as “keys”). In fact, it’s unlikely you’ll ever build an Automation without using these components, but what exactly are they?
Attributes & automation parameters enable the automation author to pass data values from one automation component to the next. During this webinar, our FME Flow Specialists will cover leveraging the three types of these output attributes & parameters in FME Flow: Event, Custom, and Automation. As a bonus, they’ll also be making use of the Split-Merge Block functionality.
You’ll leave this webinar with a better understanding of how to maximize the potential of automations by making use of attributes & automation parameters, with the ultimate goal of setting your enterprise integration workflows up on autopilot.
3. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
4. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
5. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
6. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
7. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
8. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
9. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
10. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
11. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
12. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
13. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
14. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
15. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
16. A Frame Condenser
15-1-2015A Frame Condenser
.An air cooled condenser for liquefying
vacuum steam downstream a steam
turbine.
17. A Frame Condenser
• A Frame Condensers can be applied in the following processes:
• Whizz-Wheel®: http://www.bronswerk.com/en/Whizz-Wheel/PS68/
• Waste to energy: http://www.bronswerk.com/en/Waste-to-Energy/PS47/
• Solutions: http://www.bronswerk.com/en/Solutions/PS64/
• Services: http://www.bronswerk.com/en/Service/PS69/
• District Heating: http://www.bronswerk.com/en/District-Heating/PS48/
• Diesel Power: http://www.bronswerk.com/en/Diesel-Power/PS34/
• Combined Heat Power: http://www.bronswerk.com/en/Combined-Heat--
Power/PS9/
• Combined Cycle: http://www.bronswerk.com/en/Combined-Cycle/PS29/
15-1-2015A Frame Condenser
18. A Frame Condenser
• Interested? Can we help you with your business?
• Read more about heat exchange solutions for different markets:
• Power: http://www.bronswerk.com/en/Power/MT40/
• Gas: http://www.bronswerk.com/en/Gas/MT14/
• Oil: http://www.bronswerk.com/en/Oil/MT4/
• Chemical: http://www.bronswerk.com/en/Chemical/MT24/
• Air Handling: http://www.bronswerk.com/en/Air-handling/MT30/
15-1-2015A Frame Condenser
19. A Frame Condenser
• Can we ìmprove your energy ROI?
• Ask our colleague nl.linkedin.com/pub/bram-marcus/11/24b/34b or contact
our company.
15-1-2015A Frame Condenser
20. A Frame Condenser
15-1-2015A Frame Condenser
• Like to know more about our company?
• Have a chat with Bronswerk people via our website or
• Visit our website: http://www.bronswerk.com/en/Solutions/PS64/
21. • Meet us on LinkedIn.
• https://www.linkedin.com/company/bronswerk-heat-
transfer/products?trk=top_nav_products
15-1-2015A Frame Condenser
•Join our community!
22. •Join our community!
• Conversate with us on Facebook.
• http://www.facebook.com/Bronswerk.
A Frame Condenser 15-1-2015
23. Join our community!
• Follow us on Twitter.
• https://twitter.com/bronswerk
15-1-2015A Frame Condenser