Process Plant Engineering PDF
Document Details
Uploaded by GrandMaclaurin
Batangas State University
Tags
Summary
This document provides an overview of Process Plant Engineering, focusing on its principles, objectives, and disciplines. It covers essential aspects of design, equipment, safety, optimization, and more. Process plant engineering is a specialized branch of engineering.
Full Transcript
CHAPTER 1 Process Plant Engineering -- is a specialized branch of engineering focused on designing, implementing industrial process for manufacturing plants. - It ss a multidisciplinary field focused on designing, implementing ad managing complex systems used in industrial manufacturing and...
CHAPTER 1 Process Plant Engineering -- is a specialized branch of engineering focused on designing, implementing industrial process for manufacturing plants. - It ss a multidisciplinary field focused on designing, implementing ad managing complex systems used in industrial manufacturing and processing. OVERVIEW OF PPE - Core objectives - Process design development - Project management - Safety and Environmental consideration - Control and automation - Optimization and improvement - Maintenance and troubleshooting - Quality assurance - Training and support - Innovation and research WHAT INVOLVES: 1. Process Design -- Developing the overall layout and design of the process systems. 2. Equipment Specification -- Choosing and specifying the equipment needed for the process. 3. Safety and compliance -- Ensuring that process is designed to meet the standard and regulatory requirements. 4. Optimization -- Improving existing process to increase efficiency. 5. Project management -- It includes coordinating with contractors and managing budgets. 6. Maintenance and Troubleshooting -- Developing maintenance plans and troubleshooting issues arise in plant to ensure continuous and efficient operation. 7. Integration and control -- Implementing control systems and automation monitor ensuring optimal performance. IMPORANTANCE OF PPE -- It is critically important for several reason as it plays a central role in the efficiency, safety and economically viable which contribute to the overall success of industrial operations. - Efficiency and productivity - Cost reduction - Safety - Regulatory compliance - Quality control - Environmental impact - Innovation and Competitive edge - Reliability and maintenance - Scalability - Economic impact ROLES OF PPE -- are diverse and encompass a wide range of responsibilities essential for the successful operation and management of industrial processes. ENGINEERING DISCIPLINES -- Designing and managing process plants involves a combination of multiple engineering disciplines. Each disciplines contributes a specific expertise to ensure that the plant operates efficiently safely and effectively. 1. Chemical Engineering- Focus on chemical process involved 2. Mechanical Engineering -- Involved in the design and specification of mechanical system and equipment 3. Electrical Engineering -- handles electrical systems and control systems within the plant 4. Instrumentation and Control Engineering -- Focus on measurement and control process variables 5. Civil Engineering -- Address the structural and infrastructural aspects of plants 6. Environmental Engineering -- Ensures that the plant meets the environmental regulations and minimize impact 7. Industrial Engineering -- Focuses on optimizing process efficiency and operations 8. Safety Engineering -- Ensure that the plant operates safely and meets safety regulation 9. Systems Engineering -- Managing the integration of various engineering systems and components. 10. Project Management -- Planning and execution of plant design project 11. Materials Engineering -- Focuses on selecting and testing materials used in plant construction and operation CHAPTER 2 INSTRUMENTATION -- It is composed of variety of devices and systems used to measure, monitor and control physical quantities in industrial processes. 1. Pressure Transducers -- Measure the pressure of gas 2. Temperature Sensors- Measure temperature 3. Flow meter -- measure the flow rate of liquid or gas 4. Level sensor -- detect the level of liquid or fluid in a container 5. pH meter -- measure the acidity or alkalinity of a solution 6. Gas Analyzer -- measure the concentration of gas in mixture 7. Strain gauges -- Measure the amount of deformation or strain in a material 8. Data loggers -- Record data from various sensors over time 9. Flow controllers -- regulate the flow rate of liquid or gas 10. Vibration sensors -- Monitor vibrations in machinery to detect imbalances or potential failures. MECHANICAL EQUIPMENT AND SYMBOLS a. Pumps -- It is essential for moving fluids from one location to another b. Compressors -- used to increase the pressure of gases by reducing their volume c. Heat exchangers -- it is used to transfer heat between two or more fluids without them mixing (HOW? EXPLAIN) d. Fans -- they are mostly used in ventilation e. Blowers -- it is designed to move or displaces the air the fan made f. Heat recovery system -- it is design to capture and reuse waste from various process g. Storage tank and vessel -- It is used for holding and storing fluids gas and other materials h. Filters -- used to remove contaminants or particles from fluids to improve quality i. Separators -- it is designed to separate different components such as density, size or chemical affinity j. Mixers -- use to blend combine or stir materials to achieve a certain mixture k. Agitators - use to blend combine or stir materials to achieve a certain mixture l. Motor -- It provide the power and control needed to drive machinery and equipment m. Drives -- Control the speed and torque of an AC motor n. Conveyers -- used to transport goods materials within industrial settings and they help streamline operation o. Elevator- used to elevate equipment p. Boiler -- used to generate steam and they operate by heating water or other fluids to produce steam or hot water. ELECTRICAL EQUIPMENT TYPES AND SYMBOLS -- they are essential for understanding electrical diagrams and schematics. - Power supply equipment Transformer -- steps up or down voltage Battery -- Provides DC voltage Generator -- Converts mechanical energy to electrical energy - Switch and relays Single Pole Single Throw (SPST) switch -- simple on and off switch Single Pole Double Throw (SPDT) switch -- switch that routes a signal to one of two outputs - Protective Device Fuse -- protects circuits by breaking the connection when current exceeds Circuit breaker -- automatically interrupts the circuit to protect against overload - Load devices Lamp -- Converts electrical energy to light Motor -- Converts electrical energy to mechanical Resistor -- Limits current flow in a circuit - Measuring instruments Voltmeter -- measure voltage Ammeter -- measure current Ohmmeter -- measure resistance - Ground -- reference point in electrical circuit from which voltages are measured VALVE TYPES Gate valve -- used to start or stop the flow of fluid; not typically used for regulating flow Globe valve -- used for throttling flow making it suitable for regulating flow Ball valve -- provides quick on/off control with minimal pressure drop; not ideal for throttling Butterfly valve -- used for isolating flow especially in large-diameter pipes Check valve -- prevents back flow, ensuring one way flow system Diaphragm valve -- ideal for controlling flow of corrosive, abrasive or dirty fluids Relief Valve -- automatically releases pressure to protect system from overpressure Needle valve -- provides precise flow control particular in low-flow applications Solenoid valve- Electrically controlled valve used for automatic fluid control CHAPTER 3 PETROCHEMICALS -- are non-fuel compounds derived from crude oil and natural gas and has the ability to create diverse range of polymers. - There are 10% bio ethanol on a gas station Base chemicals can be classified in 2 groups Olefin -- have chain of carbon atoms as their backbone Aromatics -- contains ring of carbon atom at the core of molecule The 2 cracking methods used in olefin plant cracker are thermal cracking (high temp) and cat cracking (using catalyst) Figure 6. (Explain) page 85 Ethylene -- petrochemical industry's key building block. THE MAJOR PLASTIC OR POLYMERS Polymerization -- is the linking of individual molecules or monomers such as ethylene into long chains of polymers such as polyethylene. Bulk/gas phase polymerization -- Most common production methods and is used in the manufacture of polyethylene and polypropylene Solution polymerization -- the monomer is dissolved in a solvent and resultant polymer is also soluble Slurry polymerization -- the polymer is produced as slurry or paste from solvent-based system Suspension polymerization -- this process is used when both the monomer and polymer are insoluble in the solvent but catalyst is soluble. Emulsion polymerization -- this high-cost method used in manufacture of special later polymers PETROCHEMICAL PROCESSES -- they are important in producing wide range of products essential in modern life including fuels, chemicals plastics and fertilizers. 1. Crude oil distillation -- the first step in refining crude oil where crude oil is heated and separated into different components base on their boiling points. 2. Steam cracking -- process where hydrocarbon (typically naphtha or ethane) is subjected to high temperature in the presence of steam 3. Catalytic cracking -- a process that uses catalyst to breakdown larger hydrocarbon 4. Hydrocracking -- process that combines hydrogen with heavy hydrocarbon in the presence of catalyst to produce lighter products 5. Reforming -- process where naphtha is converted into higher octane gasoline 6. Alkylation -- process that combines smaller molecules with larger molecules to produce high octane gasoline 7. Isomerization -- process that rearranges the structure of hydrocarbon to improve their properties 8. Aromatics production -- process such as reforming and extraction are used to produce aromatic hydrocarbons 9. Olefin production -- processes like steam cracking are used to produce olefins 10. Polymerization -- process of converting monomers into polymers through chemical reaction Polyethylene (PE) -- used in packaging, containers and films Polypropylene (PP) -- used in automotive parts, textiles and packaging Polyvinyl Chloride (PVC) -- Used in pipes, flooring and electrical insulation 11. Methanol production -- methanol is produced from natural gas through steam reforming and methanol synthesis 12. Urea production -- urea is produced from ammonia and CO2 though Haber-Bosch process 1. Crude oil- complex mixture of hydrocarbons extracted from earth 2. Natural Gas -- mixture of hydrocarbon primarily methane extracted from underground reservoir 3. Naphtha -- light distillate fraction from crude oil 4. Ethane -- byproduct of natural gas processing 5. Propane -- hydrocarbon gas extracted from natural gas processing 6. Butane -- Gas separated from natural gas 7. Aromatics -- derived from catalytic reforming of naphtha 8. Methanol -- produced from natural gas through steam reforming 9. Ammonia -- Produce from natural gas using Haber-Bosch process 10. Coal -- can be used to produce syngas which then converted into chemicals like methanol/ammonia 11. Syngas -- mixture of hydrogen and carbon monoxide produce from natural gas 12. Renewable feedstocks -- example bioethanol biodiesel and biogas KEY CONSIDERATION IN RAW MATERIAL SELECTION - Availability - Cost - Quality - Environmental impact - Sustainability