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Distribution part

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Tarun kumar
Tarun kumar

This document discusses key considerations for designing a water distribution system including: 1) The type of water flow (continuous or intermittent) and method of distribution (gravity or pumping). 2) Estimating future demand based on population growth and industrial/firefighting needs. 3) Factors that influence pipe sizing such as hydraulic gradient, flow velocity, and design life. 4) Common pipe joint types like butt-welded, socket-welded, threaded, grooved, flanged, and compression joints and their relative costs, strengths, and installation complexity.

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DISTRIBUTION SYSTEM
 Type of flow- whether continuous or intermittent.  Method of distribution- whether by gravity or by pumping.  Probable future demand based on increase in population. This also includes the industrial demand as well as fire –fighting requirements.  Period to be considered in with life of pipes used. The system should be designed anticipating the future of the town or city.
Distribution part
 Hydraulic Gradient: A line joining the points of highest elevation of water in a series of vertical pipes rising from a pipeline in which water flows under pressure.  According to HAZEN- WILLIAMS the flow-formula is written as: V=velocity of flow in pipe m/sec. M= radius of the pipe in m. I= Hydraulic gradient. C=friction coefficient whose valve depends on type of pipe used.
0.63 0.54 V = 0.85 C . M . I
a) Prepare a contoured plan of the city or town, locating the positions of districts or distribution zones with their population, service reservoirs, pumping stations, main roads and streets and other small features. A small scale (1/10,000) may be used. b)Estimating the rate of demand for all purposes including fire demand and determining the quantity flowing in each section of pipe lenght. This gives the average daily flow in the pipe. The max flow will be 3 times. c) Assuming the pipe sizes, The velocity of flow varies 0.9-1.2 m/sec.
Distribution part
 A point at which parts of an artificial structure are joined. Types: 1. Butt-welded Joints 2. Socket-welded Joints 3. Threaded or Screwed Joints 4. Grooved Joints 5. Flanged Joints 6. Compression Joints
 Butt-welding is the most common method of joining piping used in large commercial, institutional, and industrial piping systems.  Material costs are low, but labor costs are moderate to high due to the need for specialized welders and fitters.
 Socket-welded construction is a good choice wherever the benefits of high leakage integrity and great structural strength are important design considerations.  Construction costs are somewhat lower than with butt-welded joints due to the lack of exacting fit-up requirements and elimination of special machining for butt weld end preparation.
 Threaded or screwed piping is commonly used in low-cost, noncritical applications such as domestic water, fire protection, and industrial cooling water systems.  Installation productivity is moderately high, and specialized installation skill requirements are not extensive.  Rapid temperature changes may lead to leaks due to differential thermal expansion between the pipe and fittings.
Distribution part
 The main advantages of the grooved joints are their ease of assembly, which results in low labor cost, and generally good leakage integrity.  They allow a moderate amount of axial movement due to thermal expansion, and they can accommodate some axial misalignment.  The grooved construction prevents the joint from separating under pressure.
Distribution part
 Flanged connections are used extensively in modern piping systems due to their ease of assembly and disassembly; however, they are costly.  Contributing to the high cost are the material costs of the flanges themselves and the labor costs for attaching the flanges to the pipe and then bolting the flanges to each other.  Flanges are normally attached to the pipe by threading or welding, although in some special cases a flange-type joint known as a lap joint may be made by forging and machining the pipe end.
Distribution part
 Compression sleeve-type joints are used to join plain end pipe without special end preparations.  These joints require very little installation labor and as such result in an economical overall installation. Advantages include the ability to absorb a limited amount of thermal expansion and angular misalignment and the ability to join dissimilar piping materials, even if their outside diameters are slightly different.
Distribution part

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Distribution part

  • 2.  Type of flow- whether continuous or intermittent.  Method of distribution- whether by gravity or by pumping.  Probable future demand based on increase in population. This also includes the industrial demand as well as fire –fighting requirements.  Period to be considered in with life of pipes used. The system should be designed anticipating the future of the town or city.
  • 4.  Hydraulic Gradient: A line joining the points of highest elevation of water in a series of vertical pipes rising from a pipeline in which water flows under pressure.  According to HAZEN- WILLIAMS the flow-formula is written as: V=velocity of flow in pipe m/sec. M= radius of the pipe in m. I= Hydraulic gradient. C=friction coefficient whose valve depends on type of pipe used.
  • 5. 0.63 0.54 V = 0.85 C . M . I
  • 6. a) Prepare a contoured plan of the city or town, locating the positions of districts or distribution zones with their population, service reservoirs, pumping stations, main roads and streets and other small features. A small scale (1/10,000) may be used. b)Estimating the rate of demand for all purposes including fire demand and determining the quantity flowing in each section of pipe lenght. This gives the average daily flow in the pipe. The max flow will be 3 times. c) Assuming the pipe sizes, The velocity of flow varies 0.9-1.2 m/sec.
  • 8.  A point at which parts of an artificial structure are joined. Types: 1. Butt-welded Joints 2. Socket-welded Joints 3. Threaded or Screwed Joints 4. Grooved Joints 5. Flanged Joints 6. Compression Joints
  • 9.  Butt-welding is the most common method of joining piping used in large commercial, institutional, and industrial piping systems.  Material costs are low, but labor costs are moderate to high due to the need for specialized welders and fitters.
  • 10.  Socket-welded construction is a good choice wherever the benefits of high leakage integrity and great structural strength are important design considerations.  Construction costs are somewhat lower than with butt-welded joints due to the lack of exacting fit-up requirements and elimination of special machining for butt weld end preparation.
  • 11.  Threaded or screwed piping is commonly used in low-cost, noncritical applications such as domestic water, fire protection, and industrial cooling water systems.  Installation productivity is moderately high, and specialized installation skill requirements are not extensive.  Rapid temperature changes may lead to leaks due to differential thermal expansion between the pipe and fittings.
  • 13.  The main advantages of the grooved joints are their ease of assembly, which results in low labor cost, and generally good leakage integrity.  They allow a moderate amount of axial movement due to thermal expansion, and they can accommodate some axial misalignment.  The grooved construction prevents the joint from separating under pressure.
  • 15.  Flanged connections are used extensively in modern piping systems due to their ease of assembly and disassembly; however, they are costly.  Contributing to the high cost are the material costs of the flanges themselves and the labor costs for attaching the flanges to the pipe and then bolting the flanges to each other.  Flanges are normally attached to the pipe by threading or welding, although in some special cases a flange-type joint known as a lap joint may be made by forging and machining the pipe end.
  • 17.  Compression sleeve-type joints are used to join plain end pipe without special end preparations.  These joints require very little installation labor and as such result in an economical overall installation. Advantages include the ability to absorb a limited amount of thermal expansion and angular misalignment and the ability to join dissimilar piping materials, even if their outside diameters are slightly different.