Satish Lele
lelepiping@gmail.com

This is a program for Skill Development and Bridging the Gap between Manual and Computer work. I offer Training of Basic Fundamentals and How to Use my Software to a batch of 5 to 10 people in your office. This can speed up Drawing work using my own Software, compared to conventional methods. This is a package, which can run on any CAD program and is very simple and easy to use. The package is given FREE of CHARGE to the company.

System drawings (PFDs and P&IDs)

Process Flow Drawing (PFD): A process flow diagram (PFD) is a diagram commonly used in chemical and process engineering to indicate the general flow of plant processes and equipment. The PFD displays the relationship between major equipment of a plant facility and does not show minor details such as piping details and designations.
A Process Flow Diagram (PFD) shows the relationships between the major components in the system. PFD also tabulate process design values for the components in different operating modes, typical minimum, normal and maximum. A PFD does not show minor components, piping systems, piping ratings and designations.

    Typically, process flow diagrams of a single unit process will include the following:
  • Major equipment items.
  • All equipment sizes with relevant MEB information as required.
  • All equipment names and numbers
  • Process piping.
  • All major process lines.
  • All major utility lines involving material flow.
  • All stream numbers, temperatures, pressures, flows.
  • Control valves and other major valves.
  • Connections with other systems.
  • Major bypass and recirculation streams.
  • Operational data (temperature, pressure, mass flow rate, density, etc.).
  • Process stream names.
    Conveys the major processing steps represented by the equipment:
  • Useful for conveying the heat and material balances.
  • Useful for conveying major pieces of equipment.
  • Useful for conveying processing conditions.
  • Useful for conveying utilities.
    The goal is to present the most amount of information with the least amount of effort on the part of the reader.
  • The flowsheet should generally flow from left to right.
  • The flowsheet should not be cluttered - use multiple sheets.
  • The flowsheet should be in landscape with the bound edge at top.
  • The equipment should be drawn in approximately relative size, e.g. towers larger than drums, exchangers larger than pumps etc.
  • The major towers and reactors are generally on one, or nearly one, level.
  • The reader should be able to follow Process and Instrumentation Diagrams with his or her eye.
  • The streams should have the minimum of direction changes.
  • The streams that enter across the battery limits should be on the left.
  • The streams that leave across the battery limits should be on the right.
  • The streams that move to the next sheet should leave on the right.
  • The streams that recycle to earlier sheets should leave on the left.
    Process flow diagrams generally do not include:
  • Pipe classes or piping line numbers.
  • Process control instrumentation (sensors and final elements).
  • Minor bypass lines.
  • Isolation and shutoff valves.
  • Maintenance vents and drains.
  • Relief and safety valves.
  • Flanges.

Process flow diagrams are high levels drawings usually of multiple process systems within a large industrial plant and may be called block flow diagrams or schematic flow diagrams.


Process and Instrumentation Drawing (P&ID): The P&ID shows the interconnection of process equipment and the instrumentation used to control the process. In the process industry, a standard set of symbols is used to prepare Process and Instrumentation Diagrams drawings of processes. Process and Instrumentation Diagrams is a diagram in the process industry which shows the piping of the process flow together with the installed equipment and instrumentation.
    For processing facilities, a P&ID is a pictorial representation of the following:
  • Key piping and instrument details.
  • Relationship between control instruments and process equipment.
  • Control and shutdown schemes.
  • Safety and regulatory requirements.
  • Basic start up and operational information.
  • Instrumentation and designations.
  • Mechanical equipment with names and numbers.
  • All valves and their identifications.
  • Process piping, sizes and identification.
  • Miscellanea -vents, drains, special fittings, sampling lines, reducers, increasers and swages.
  • Permanent start-up and flush lines.
  • Flow directions.
  • Interconnections references.
  • Control inputs and outputs, interlocks.
  • Interfaces for class changes.
  • Computer control system input.
  • Identification of components and subsystems delivered by others.
    What information can you get?:
  • For Equipment: Outline/Internals.
  • For Piping: Line No./Size/Material/Insulation/Line Configuration/Piping Component Type.
  • For Instrument: Tag No./Function/Control Method.
    P&ID is used for
  • Detail Engineering of each disciplines Piping layout / Material Purchase Instrument Logic / DCS Plan, etc.
  • Planning of Construction / Commissioning /Plant Operation / Maintenance

As a rule P&IDs do not have a drawing scale and present only the relationship or sequence between components. Just because two pieces of equipment are drawn next to each other does not indicate that in the plant the equipment is even in the same building; it is just the next part or piece of the system. These drawings only present information on how a system functions, not the actual physical relationships. Because P&IDs provide the most concise format for how a system should function, they are used extensively in the operation, repair, and modification of the plant.
P&IDs play a significant role in the maintenance and modification of the process that it describes. It is critical to demonstrate the physical sequence of equipment and systems, as well as how these systems connect. During the design stage, the diagram also provides the basis for the development of system control schemes, allowing for further safety and operational investigations, such as the hazard and operability study(HAZOP)

    Key Points:
  • Place equipment and its components.
  • Connect main piping.
  • Complete control valve loop.
  • Place other instrument and connect signals.
  • Indicate safety devices including alarm.
  • Place piping components (Valve / Fitting) as required.
  • Check detail and add items required including vent / drain connection
  • Identify and draw Piping and Instrument Diagram (P&ID) symbols frequently used for valves instruments and equipment.

  • Identify and draw isometric symbols used for screwed and butt welded fittings for piping systems.

  • Identify and draw pipe General Arrangement (GA) symbols that are used for piping general arrangement drawings.

  • Sketch single line piping isometric for the piping assembly spools.


Trial programs are full scale programs without option to insert Valves.
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