Water Resources Engineering 1 PDF

Summary

This document defines and classifies the application and control of water resources, focusing on agricultural, industrial, residential, recreational, and environmental uses. It discusses various water sources, including groundwater, rivers, lakes, and reservoirs, exploring examples of applications in the Philippines.

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WATER RESOURCES ENGINEERING 1 Definition & Classification of Application Control and Use of Water E Engr. JJohn h MManuell B.Vergel BV l BS-CE, MS-CE Review of...

WATER RESOURCES ENGINEERING 1 Definition & Classification of Application Control and Use of Water E Engr. JJohn h MManuell B.Vergel BV l BS-CE, MS-CE Review of Hydrology y Review of Hydrology Definition & Classification of Application / Control and Use of Water. y Water Resources – are sources of usually fresh water that are useful or potentially useful to society. Use of water includes: c u es: a) Agricultural (70% of worldwide water user) b) Industrial (22% of worldwide water user) c) Residential (8% of worldwide water user) d Recreational d) R i l e) Environmental activities Examples of sources: Groundwater, Rivers, Lakes and Reservoirs Definition & Classification of Application / Control and Use of Water. y Agricultural – for crops irrigation / aquaculture Balog-Balog Multi Purpose Project (BBMPII) at San Jose, Tarlac Irrigation Capacity = 34,410 hectares (23,000 farmers) Hydropower Generation = 43.5 MW Dam Storageg Capacity p y = 560 Million Cubic Meters ((MCM)) Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: a) Hydroelectric plants; * Dam D /R Reservoiri &R Run-off ff the th river; i b) Thermo electric power plants (water cooling); * Coal, Nuclear, Geothermal, Solar Thermal Electric, Biomass c) Ore and oil refineries (chemical process); d) Manufacturing plant (solvent). Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: a) Hydroelectric plants; D /R Dam Reservoir i R Run-off ff the th River Ri San Roque Hydroelectric Power Plant (2003) Capacity = 345 MW (3rd Largest in the Philippines) Location: San Manuel & San Nicolas, Pangasinan Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: b) Thermo electric power plants (water cooling); Coal Power Plant Geothermal Power Plant Coal Fired Thermal Power Plant (1984, 1995 DMCI) Palinpinion Geothermal Plant (1983, 1995) Capacity = 600 MW (3rd largest in the Philippines Capacity = 192 MW (5th largest in the Philippines) Location: Calaca, Batangas Location: Valencia, Negros Oriental Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: b) Thermo electric power plants (water cooling); Solar Thermal Electric Plant Biomass Power Plant 160 Has Solar Farm (2016 Solar Philippines) Biomass Plant (2015 IBEC ) Capacity = 63.3 MW (3rdlargest in the Philippines) Capacity = 18 MW (7th largest in the Philippines) Location: Calatagan, Batangas Location: Alicia, Isabela Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: b) Thermo electric power plants (water cooling); Nuclear Power Plant Bataan Nuclear Power Plant (1976 Never Operated) Capacity p y = 621 MW ((onlyy plant) p ) Location: Morong , Bataan Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: c) Ore and Oil refineries (chemical process); G ld Silver Gold, Sil and d Copper C Mines Mi Masbate Mine, Philippines (2013) Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: d) Manufacturing Plant (solvent); F d Food P Paper Gardenia Bakeries Trust International Paper Corp. (TIPCO) Definition & Classification of Application / Control and Use of Water. y Industrial– which includes: d) Manufacturing Plant (solvent); Ch i l Chemicals St l Steel Unilab Steel Asia Definition & Classification of Application / Control and Use of Water. y Residential– potable water supply (Water Treatment) Manila Water Treatment Plant MayniladTreatment Plant Definition & Classification of Application / Control and Use of Water. y Recreational– R ti l smallll growing i percentage t off usage off water t Sky Water Park Kayak at Camayan Beach Resort Definition & Classification of Application / Control and Use of Water. y Environmental E i t lAActivities– ti iti environmental i t l flows fl (10% off available flow) & fish ladders to maintain aquatic habitat (ecosystem support). support) Environmental flow Fish ladders Definition & Classification of Application / Control and Use of Water. y Sources S off FFresh hWWater t – groundwater, d t river, i llake k andd reservoirs. Laguna Lake Angat Reservoir G Groundwater d t River Definition & Classification of Application / Control and Use of Water. y Distribution of water on Earth Definition & Classification of Application / Control and Use of Water. y Fresh water is renewable resource like soil and air. y The world is supplied pp byy clean and fresh water and it is decreasing. y Water is one of our most critical resources, but b aroundd the h world ld it is under threat. y Water demand already exceed supply in many parts of the world and as the world population continues to rise, so too the h water demand. Definition & Classification of Application / Control and Use of Water. y Water Resources Engineering – plays a vital role in optimal, planning, design and operation of water resource system. y Applications include the design of hydraulic structures, such as sewage conduits, dams and breakwaters, the management off waterways, suchh as erosion i protection i andd flood protection, and environmental management, such as prediction of the mixing and transport of pollutants in surface water. y Hydroelectric-power y p development, p , water supply, pp y, irrigation and navigation are some familiar applications of water resources engineering involving the utilization of water for f beneficial b fi i l purposes. Definition & Classification of Application / Control and Use of Water. y Control of Water– so that it will not cause excessive damage to property, inconvenience to the public, or loss of life. e. Applications pp cat o s are: a e: a) Flood Mitigation; b) Storm Drainage; c) Sewerage; d Highway d) Hi h Culvert C l D Design. i Definition & Classification of Application / Control and Use of Water. y Flood Mitigation– involves the management and control of flood water movement, such as redirecting flood run-off tthrough oug the t e use of o flood oo walls, wa s, levees, evees, dredging e g g and a flood oo gates, rather than trying to prevent floods altogether. Flood Wall Mangahan Floodway (1983 , NHCS Marikina River) Definition & Classification of Application / Control and Use of Water. y Flood Mitigation Dredging San Roque Dam (gradual release) Definition & Classification of Application / Control and Use of Water. y Storm Drainage– involves is designed to drain excess rain and groundwater from impervious surfaces such as paved streets, st eets, car ca parks, pa s, parking pa g lots, ots, footpaths, ootpat s, sidewalks, s ewa s, and a roofs Curb Inlet Gutter Inlet Definition & Classification of Application / Control and Use of Water. y Storm Drainage Combination Definition & Classification of Application / Control and Use of Water. y Sewerage – is an artificial conduit, usually underground, for carrying off waste water and refuse, as in a town or city.y y It can either be storm sewer system or sanitary sewer system or combined. Definition & Classification of Application / Control and Use of Water. y Highway Culvert Design– is a structure that allows water to flow under a road, railroad, trail, or similar oobstruction st uct o from o one o e side s e to tthee other ot e side. s e. Definition & Classification of Application / Control and Use of Water. y Utilization of Water– use of water for beneficial purposes. purposes Applications are: a) Municipal Water Supply; b) Irrigation; c) Hydroelectric H d l i PPower D Development; l d) Navigation Improvements. y Water Quality Management– pollution control. Pollution threatens the utility of water for municipal and irrigation uses. Definition & Classification of Application / Control and Use of Water. y Water Quality Management Definition & Classification of Application / Control and Use of Water. y Planning of Water Resource Project Definition of Technical Political incentive alternatives feasibility Social and Financial Economic environmental feasibility feasibility acceptability Political practicality Definition & Classification of Application / Control and Use of Water. y The Future of Water Resources Engineering 1. Modern civilization is far more dependent on water than were the civilizations of the past. past 2. Modern Standards of personal cleanliness require vastly more water that was used a century ago.ago 3. Increasing population requires expanded acreage of agriculture. agriculture 4. Increasing urban population require more attention to storm drainage drainage, water supply supply, and sewerage. sewerage 5. Industrial progress finds increasing uses for water in process industries and for electric-power electric po er production. production Definition & Classification of Application / Control and Use of Water. y The Future of Water Resources Engineering 6. The water-resources engineers of the future will find themselves deeply involved with new technology and new concepts. 7 Reclamation of wastewater 7. wastewater, weather modification, modification land management to improve water yield, and new water-saving techniques. 8. The conflict between preserving our ecosystem and meeting the “needs” needs of people for water management must certainly lead to new approaches in water management and qquite possibly p y to new definitions of “need”. WATER RESOURCES ENGINEERING 2 Water Q Quality y Analysis y & Management g Philippine Water Resource Region Engr John Manuel B.Vergel Engr. B Vergel BS-CE, MS-CE Water Quality Analysis & Management y Introduction to Water Quality ¾ Water as universal solvent in nature contains dissolved substances, as well substances ell as gases and these substances are often identified as impurities found in water. Water Quality Analysis & Management y Introduction to Water Quality Water Quality Analysis & Management y Water Q Quality y Standards ¾ need to have legal basis for protecting water quality ¾ RA 9275 or the Philippine Clean Water Act (CWA) of 2004 defines water quality as “the characteristics of water which define its use in terms of physical, chemical, biological, bacteriological or radiological characteristics by which the acceptability of water is evaluated. evaluated ” ¾ The beneficial uses and guideline values for the different classes of waters in i the h country are specified ifi d iin the h Revised R i d Water W Q Quality li Guidelines (revision of DAO 34, series of 1990). ¾ Generally, waters in the higher classification level have more stringent water quality guideline values than waters in the lower classification f level. Thus, effluent to be discharged g into waters of higher classification level usually has stricter effluent standards than effluent to be discharged into waters of lower classification level. Water Quality Analysis & Management y Water Quality Standards (DAO 34–Stream Standard) Water Quality Analysis & Management y Water Quality Standards Water Quality Analysis & Management y Water Quality Characteristics of Water: ¾ Physical Characteristics ¾ Chemical Ch l Ch Characteristics ¾ Biological Characteristics Water Quality Analysis & Management y Physical Characteristics of Water ¾ These categories are apparent to the senses of smell taste sight and touch. touch ¾ Categories under: ƒ Total Solids ƒ Turbidityy ƒ Color ƒ Taste and Odor ƒ Temperature Water Quality Analysis & Management y Physical y Characteristics of Water ¾ Solids: ƒ Determined by evaporating a sample and weighing the dry residue. id ƒ Regards to size, solids in waste water can be classified as suspended, settleable, colloidal, or dissolved. ƒ Solids l d typically ll include l d inorganic solids, suchh as silt, l sand, d gravel, l and clay from riverbanks, and organic matter, such as plant fibers and microorganisms g from natural or manmade sources. ƒ Siltation describes the suspension and deposition of small sediment particles in water bodies. bodies (Same as sedimentation=>sediments) Water Quality Analysis & Management y Physical Characteristics of Water ¾ Solids: ƒ In I water treatment, the h most effective ff means off removing solids (except for colloids and other dissolved solids) l d ), from f water is by b filtration. fl Water Quality Analysis & Management y Physical Characteristics of Water ¾ Solids: (DAO 34) Legend: g (f) Not more than 30% increase (g) Not more than 30 mg/L increase (h) Not more than 60 mg/L increase ( ) Do (i) D not apply if natural background is hi h iin higher concentration Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: ƒ is used to measure the clarity of water. water ƒ Although Alth h algal l l bl blooms can make k waters t tturbid, bid iin surface f water, most turbidity is related to the smaller inorganic components of the suspended solids burden, burden primarily the clay particles. ƒ Microorganisms and vegetable material may also contribute to turbidity. turbidity Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: ƒ Usually U ll causedd bby clay, l silt l andd soill particles l andd other h colloidal impurities. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: 1. Types off SSolids T lid AAccording di tto Ch Chemical i lPProperty: t Organic Inorganic – include salts and minerals 2 2. Types of Solids According to Size: Suspended > 1 mm (larger than bacteria) Colloidal between 1 mm and.001 001 mm Dissolved <.001 mm Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: ƒ Measuring Turbidity: T bd 1. Secchi disk method – involves lowering a special black and white disk called a Secchi disk into the water and determining the maximum depth at which it is visible - results are reported in meters Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: ƒ Measuring Turbidity: T bd 2. Chemical titration method - involves titrating a turbidity solution into a sample until an equilibrium point is reached. - results are reported in Nephlometer Turbidity Units (NTU) or Jackson Turbidity Units (JTU) -in general, a turbidity value of > 40 NTU for at least twenty-four hours indicates a problem. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Turbidity: ƒ Measuring Turbidity: T bd 3. Turbidemeter- measuring the interferance to the passage of light through a water sample. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Color: ƒ Pure P water is colorless. l l ƒ Water takes on color when foreign substances such as organic matter from soils, vegetation, minerals, and aquatic organisms are present. ƒ The obvious problem with colored water is that it is not acceptable to the public. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Color: ƒ Color C l ini water iis classified l ifi d as either i h true color l or apparent color. l i. True color - water whose color is partly due to dissolved solids that remain after remo removal al of suspended matter matter. (In water ater treatment, true color is the most difficult to remove). ii. Apparent color - color contributed by suspended matter Water Quality Analysis & Management y Physical Characteristics of Water ¾ Color: (DAO34) PCU – Photo Conductor Unit Water Quality Analysis & Management y Physical Characteristics of Water ¾ Taste and Odor: ƒ T&O T O can also l result l as a byproduct b d off chlorine disinfection. Drinking water should be free from any objectionable taste or odor at the point of use. ƒ Odors are generated by gases produced by ddecomposition iti off organic i matter or by b substances added to the wastewater. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Taste and Odor: ƒ Water W that h tastes bbitter is usually ll alkaline, lk l while h l salty l water is commonly the result of metallic salts. ƒ When water has a taste but no accompanying odor, the cause is usually ll inorganic contamination ƒ Water has both taste and odor, the likely cause is organic materials Water Quality Analysis & Management y Physical Characteristics of Water ¾ Temperature: ƒ Temperature T increases in surface f waters is that h it affects ff the h solubility of oxygen in water, the rate of bacterial activity, and the rate t att which hi h gases are ttransferred f d tto andd ffrom th the water. t ƒ temperature has h an effect ff on the h rate at which h h chemicals dissolve and react. ƒ Determines which fish species can survive. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Temperature: ƒ Removes R impurities andd its transport. ƒ Most individuals find that water having a temperature between 10–15°C is most palatable. Water Quality Analysis & Management y Physical Characteristics of Water ¾ Temperature: (DAO 34) Water Quality Analysis & Management y Chemical Characteristics of Water ¾ The most important Chemical Characteristics are: ƒ Total T l Dissolve D l Solids S l d (TDS) ƒ Alkalinity ƒ Hardness ƒ Fluoride uo e ƒ Metals ƒ Organics O i ƒ Nutrients Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Chemical impurities cause water to behave as either an acid or a base. ¾ pH is a important factor that influences the corrosiveness of the water, chemical dosages necessary for proper disinfection, and the ability bilit tto ddetect t t contaminants t i t eitherith an acid or a base. ¾ measure of how acidic or alkaline the water on a scale of 1-14 log [H3O+] pH = -log Water Quality Analysis & Management y Chemical Characteristics of Water ¾ pH: (neutral condition, pH=7) ((acidic d condition d pH9) Water Quality Analysis & Management y Chemical Characteristics of Water ¾ The principal contaminants found in water are shown in Table. ¾ These chemical constituents are important because each one affects water use in some manner; each one either restricts or enhances specific uses. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Total Dissolve Solids (TDS): ƒ TDS constitutes a part off totall solids l d in water; it is the h material remaining in water after filtration. (minerals, salts, metals cations or anions dissolved in water). metals, water) ƒ Dissolved l d solids l d may bbe organic or inorganic. ƒ The organic dissolved constituents of water come from the decay products of vegetation, from organic chemicals, and from organic gases. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Total Dissolve Solids (TDS): ƒ Dissolved D l d solids l d can bbe removedd from f water by b distillation, d ll electrodialysis, reverse osmosis, or ion exchange. ƒ Dissolved minerals, gases, and organic constituents produce aesthetically h ll displeasing color, taste, and odors. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Total Dissolve Solids (TDS): (DAO 34) Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Alkalinity: ƒ It is a measure of water’s abilityy to neutralize acid or reallyy an expression of buffering capacity. ƒ The Th major j chemical h i l constituents i off alkalinity lk li i iin naturall water supplies are the bicarbonate, carbonate, and hydroxyl ions. ƒ It is important for fish and aquatic life because it protects or buffers against rapid pH changes. ƒ Alkalinity levels affect the efficiency of certain water treatment processes, especially i ll th the coagulation l ti process. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Hardness: ƒ It is due to the presence of multivalent metal ions that come from minerals dissolved in water. ƒ In freshwater, the primary ions are calcium and magnesium. ƒ Hardness is classified as carbonate hardness or noncarbonate hardness. ƒ Carbonate hardness is equal q to alkalinityy but a noncarbonate fraction may include nitrates and chlorides. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Hardness: ƒ Hardness H d is either h temporary or permanent. ƒ Carbonate hardness (temporary hardness) can be removed byy boiling. g ƒ Noncarbonate hardness cannot be removed by boiling and is classified as permanent. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Hardness: ƒ Hardness values are expressed p as an equivalent q amount or equivalent weight of calcium carbonate. (see table below) ƒ Washing with a bar of soap soap, there is a need to use more soap to get a lather whenever washing in hard water. (economic loss) Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Hardness: ƒ Advantages Ad to bbe gainedd ffrom usage off hhardd water: 1. Hard water aids in the growth of teeth and bones. 2. Hard water reduces toxicity to many by poisoning with lead oxide from lead pipelines. pp 3. Soft waters are suspected to be associated with cardiovascular diseases.. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Fluoride: ƒ Fluoride is seldom found in appreciable pp quantities q in surface f waters and appears in groundwater in only a few geographical regions. ƒ It sometimes found in a few types of igneous or sedimentary rocks. ƒ Fluoride is toxic to humans in large quantities and is also toxic to some animals. l Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Fluoride: ƒ Drinkingg water containingg a proper p p amount of fluoride can reduce tooth decay by 65% in children between ages 12 to 15. (used for small concentration about 1.0 mg/L in drinking water) ƒ Discoloration of teeth mayy result for larger g concentration of fluoride (>2.0 mg/L). Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Metals: ƒ Metal ions are dissolved in groundwater and surface water when the water is exposed to rock or soil containing the metals, usually in the form of metal salts. ƒ Metals can also enter with discharges g from sewage treatment plants, industrial plants, and other sources. ƒ The metals most often found in the highest concentrations in natural waters are calcium and magnesium. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Metals: ƒ The higher g the concentration of these metal ions, the harder the water; ƒ Even E in i smallll quantities, i i toxic i metals l iin ddrinking i ki water are harmful to humans and other organisms. (Arsenic, barium, cadmium,, chromium,, lead,, mercury, y, and silver are toxic metals) ƒ Arsenic, cadmium, d lead, l d andd mercury, allll cumulative l toxins, are particularly hazardous. Water Quality Analysis & Management y Chemical Characteristics of Water ¾Metals: ƒ Organic chemicals in water primarily emanate from synthetic compounds that contain carbon, such as polychlorinated b h l ddioxin, andd ddichlorodiphenyltrichloroethane biphenyls, hl d h l hl h ((allll toxic organic chemicals). ƒ Many of these compounds can cause cancer in people and birth df defects. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Organics: ƒ The p presence of organic g matter in water is troublesome for the following reasons: (1) color formation, (2) taste andd odor d problems, bl (3) oxygen depletion in streams, (4) interference with water treatment processes processes, and (5) the formation of halogenated compounds when chlorine is added to disinfect water. ƒ The general category of “organics” in natural waters includes organic matter whose h origins could ld bbe from f both b h natural sources and from human activites. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Organics: ƒ The source of organic g matter in water is from decaying y g leaves, weeds, and trees; the amount of these materials present in natural waters is usually low. ƒ Organic compounds that are solely man-made (anthropogenic), such as ppesticides and other synthetic y organic g compounds. p ƒ In water, dissolved organics g are usuallyy divided into two categories: biodegradable and nonbiodegradeable. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Organics: ƒ Biodegradable g (breakdown) material consists of organics g that can be utilized for nutrients (food) by naturally occurring microorganisms within a reasonable length of time. (alcohols, acids starches, acids, starches fats, fats proteins, proteins esters, esters and aldehydes result from domestic or industrial wastewater discharges) ƒ Some biodegradable organics can also cause color, taste, and odor problems. ƒ Nonbiodegradeable organics are resistant to biological degradation. g Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Organics: ƒ Some S organics are toxic to organisms andd are nonbiodegradeable (organic pesticides and compounds that have combined with chlorine). chlorine) ƒ Iff Surface f streams are contaminatedd via runoff ff andd washh off ff by rainfall. These toxic substances are harmful to some fish, shellfish, h llfi h predatory d t bi birds, d andd mammals. l SSome compounds d are toxic to humans. Water Quality Analysis & Management y Chemical Characteristics of Water ¾ Nutrients: y Nutrients ((biostimulents)) are essential buildingg blocks for f healthyy aquatic communities, but excess nutrients (especially nitrogen and phosphorous compounds) overstimulate the growth of aquatic weeds and algae. algae y Plants require q large g amounts of the nutrients carbon, nitrogen, g and phosphorus; otherwise, growth will be limited. y Nitrogen and phosphorous are essentiall growth h ffactors andd are the limiting factors in aquatic plant growth. Freshwater systems y are most often limited byy pphosphorus. p Water Quality & Standard y Biochemical Characteristics of Waster &WasteWater ¾ Biological organisms are in the presence of Phatogens ¾ These Th waterborne b pathogens h include l d species of: f ƒ Bacteria, ƒ Viruses, ƒ Protozoa, oto oa, ƒ Parasitic worms (helminths). Water Quality Analysis & Management y Biochemical Characteristics of Waster ¾ Bacteria: ƒ Bacteria are p present in air, water, earth, rottingg vegetation, g and the intestines of animals. ƒ Human H andd animall wastes are the h primary i source off bbacteria i iin water. ƒ Varying in shape and size from about 1-4μm and it cannot be seen by naked eye. ƒ Bacteria from these sources can enter wells that are either open att th the land l d surface f or do d nott have h watertight t ti ht casings i or caps. Water Quality Analysis & Management y Biochemical Characteristics of Waster ¾ Viruses: ƒ Smallest ll bbiological l l structures known, k so they h can only l bbe seen with the aid of an electron microscope ƒ Viruses that are excreted byy human beings g mayy become a major health hazard to public health. ƒ Waterborne viral pathogens are known to cause poliomyelitis and infectious hepatitis Water Quality Analysis & Management y Biochemical Characteristics of Waster ¾ Protozoa: y Most protozoa are harmless; only a few cause illness in humans—Entamoeba histolytica (amebiasis) being an e cept o. exception. ¾ Worms (Helminths): y Water contamination may result from human and animal waste that contains worms. worms y Worms pose hazards primarily to those persons who come into direct contact with untreated water. water Water Quality Analysis & Management y Biochemical Characteristics of Waster Water Quality Analysis & Management y Biochemical Characteristics of Waster Philippine Water Resources Region y Philippine’s pp 18 Major Basins (source: NWRB) Philippine Water Resources Region y Philippine Philippine’ss 18 Major Basins ( (source: NWRB) Philippine Water Resources Region y Philippine Philippine’ss 18 Major Basins ( (source: NWRB) Philippine Water W Resources Region y Pampanga River Basin (source: PRBFFWC ) Water Resources List: 1. Pantabangan Dam 2 Angat Dam 2. 3. Ipo Dam Etc. Et Source: DENR (IWRM Spiral of Pampanga River Basin) Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region Source: DENR (IWRM Spiral of Pampanga River Basin) Philippine Water Resources Region y Pampanga p g River Basin ((source: PRBFFWC ) Water Resources List: 1. Pantabangan Dam L i Location: P b Pantabangan, N Nueva E ij Ecija Coordinates: Lat: 15°48’52” Long: g 121°06’29” Operation: September 1, 1974 Operator: NPC T Type: R Reservoir i /DDam Dam Height: ?? Type yp of Dam: Embankment,, Earth fill River: Pampanga River Catchment Area: 853 km2 I ll d C Installed Capacity: 120 MW Purpose:Irrigation / Hydroelectric Power Plant Philippine Water Resources Region y Pampanga River Basin (source: PRBFFWC ) Water Resources List: 1 Pantabangan 1. P tb D Dam Philippine Water Resources Region y Pampanga p g River Basin ((source: PRBFFWC ) Water Resources List: 2. Angat Dam L i Location: B Brgy. San S LLorenzo, Norzagaray, N B l Bulacan Coordinates: Lat: 14°52’15” Long: g 121°08’30” Operation: October16, 1967 Operator: NPC T Type: R Reservoir i /DDam Dam Height: 131m Type yp of Dam: Concrete Water Reservoir River: Angat River Catchment Area: 568 km2 I ll d C Installed Capacity: 256 MW Purpose:Irrigation / Potable Water / Hydroelectric Power Plant Philippine Water Resources Region y Pampanga River Basin (source: PRBFFWC ) Water Resources List: 2 Angat 2. A t Dam D Philippine Water Resources Region y Cagayan River Basin WATER RESOURCES ENGINEERING 3.1 Hydroelectric Power Engr. John Manuel B.Vergel BS CE MS BS-CE, MS-CE CE Hydroelectric Power y Introduction ¾ Hydroelectric y – are electricity produced from hydropower. hydropower Waterwheels (4th Century BC) Hydropowered Watermills (mid 1770’s) ¾ Hydropower – the harnessing of flowingg water usingg a dam or other type of diversion structure to create c eate energy e e gy that t at can ca bee captured via a turbine to generate electricity Hydroelectric Power y Definition of terms ¾ Gross Head ((HG) – total difference in elevation between the water surface in the stream at the diversion and the water surface in the stream at the point where the water is returned after having been used for power; ¾ Net Head ((HN) – is the head available for energy gy production after deducting losses in friction, entrance, unrecovered velocity head in the draft tube, tube etc.. etc Net Head = Gross Head – Total System HeadLosses HN=HG-∑HL Hydroelectric Power y Definition of terms y Hydraulic y efficiency y – the ratio of the net head to ggross head. ηh = HN / HG Hydroelectric Power y Definition of terms ¾ Overall efficiency y (Turbine-Generator) – represents the fraction of the mechanical energy of the h fluid fl id convertedd to electrical energy. Also known as product efficiency. e = ηP = ηT x ηG Hydroelectric Power y Definition of terms ¾ Power Capacity p y – the maximum ppower which can be developed by the generators at normal head with full flow. Also known as maximum power. p P = Q γ HN e P = Power (KW); Q = Discharge g ((cms); ) HN = Net Head (m); e = Overall Efficiency; Hydroelectric Power y Definition of terms ¾ Firm Power – is the p power a pplant can be expected p to deliver 90% of time. Also known as minimum power. Hydroelectric Power y 3 Types of Hydropower Plants ¾ 1. Impoundment p (Reservoir) ( ) – the most common type of hydroelectric power plant. An impoundment facility typically a large hydropower system, facility, system uses a dam to store river water in a reservoir. Water released from the h reservoir i fl flows through h h a turbine, bi spinning i i iit, which hi h in turn activates a generator to produce electricity. The water may be released either to meet changing electricityy needs or to maintain a constant reservoir level. Hydroelectric Power y 3 Types of Hydropower Plants ¾ 1. Impoundment p Transmission lines - conduct electricity for homes and businesses. Dam - store water. Penstock – carries water to turbines. Generators G t – rotated t t d by b the th turbines t bi to t generate electricity. Turbines – turned by the force of the water on their blades. Cross section off conventionall hhydropower C d ffacility l that h uses an impoundment dam. Hydroelectric Power y 3 Types of Hydropower Plants ¾ 1. Impoundment p Angat Reservoir Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. 2 Diversion (run- off river) – facility channels h l a portion ti off a river through a canal or penstock. It may q not require the use of a dam. Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion ((run-off river)) ¾ Intake / Weir - it is used to collect water which will be used for power plant. From weir water will enter to the weir, intake gate leading to the connecting tunnel which go out into the run off river. After pass connecting tunnel, tunnel water will pass waterway. Also known as low head dam. dam 1.5 MW Hitoma River Hydropower Project Obi, Caramoran, Catanduanes Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run-off river) ¾ Desilting Basin- is to settle out the pparticulate matters floatingg in the water to the bottom of the construction. The water which is used for the turbine can therefore be separated from these h solids.This l d Th function f is very important because to protect other th microi hhydrod power plant l t components from the impact of sand. sand Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Spillway- are designed to permit controlled overflow at certain i points i along l the h channel h l or weir. i 900KW Cantingas River Hydropower Project 10 MW Inabasan River Hydropower Project San Fernando, Sibuyan Island, Romblon Caagutayan, San Teodoro, Oriental Mindoro Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Headrace / Waterway- usually follow contours of the hill to kkeep the h elevation l i off the h channeled h l d water andd kkeep the h potential il energy stable on the value. Hi b Hinubasan Ri River H Hydropower d P Project j Loreto, Dinagat Isaland, Surigao Norte Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Forebay / Surgetank- is usedd to controll water output difference between penstock and head race. Moreover, its p function as final separation impurities in the water such as sand and wood wood. The function of forebay tank is also as desilting b i (sand basin ( d trap). t ) Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Penstock - is water supplier ffrom head h d tankk which hi h will ill rotate the turbine. Penstock connects a high elevation to a lower elevation to the turbine 10 MW Inabasan River Hydropower Project Caagutayan, San Teodoro, Oriental Mindoro Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Powerhouse - it contains the maini equipments i to change h potential energy become electricity, they are turbine, ggenerator,, and control panel p 2.1 MW Solong River Hydropower Project San Miguel, Catanduanes Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion ((run-off river)) ¾ Turbine and Generator - are used to change water potential energy which is fallen through penstock become electricity. electricity Turbine is connected with a pulley on the generator so between water side and electricity still 8 MW Upper Villasiga Hydropower Project separated To regulate changing separated. Paliuan River, Bugasong, Antique electic is used AVR (Automatic Voltage Regulator) on the generator. Hydroelectric Power y 3 Types of Hydropower Plants ¾ 2. Diversion (run (run-off off river) ¾ Tailrace - after water rotate turbine then water will be returnedd again i to the h river i through h h specific ifi tunnell which hi h iis called ll d tail race. 900KW Cantingas River Hydropower Project San Fernando, Sibuyan Island, Romblon Hydroelectric Power y 3 Types of Hydropower Plants ¾ 3. Pump p Storage g – it works like a battery, y, storingg the electricity generated by other power sources like solar, wind and nuclear for later use wind, use. It stores energy by pumping water uphill to a reservoir at higher elevation f from a secondd reservoir i at a llower elevation. l i Wh When theh demand for electricity is low, a pumped storage facility stores energy by pumping water from a lower reservoir pp reservoir. Duringg pperiods of high to an upper g electrical demand, the water is released back to the lower reservoir and turns a turbine turbine, generating electricity. electricity Hydroelectric Power y 3 Types of Hydropower Plants ¾ 3. Pump p Storage g Hydroelectric Power y 3 Types of Hydropower Plants ¾ 3. Pump p Storage g Hydroelectric Power y 3 Types of Hydropower Plants ¾ 3. Pump p Storage g Kalayaan Pumped Storage Power Plant was built in 1982, it is the first of its kind in Southeast Asia and the only pumped storage facility in the Philippines. Kalayaan I was upgraded from 150 MW to over 168 MW. Kalayaan II was built with a guaranteed capacity of 174.3 MW. The Kalayaan Complex serves as large peaking facility for the Luzon Grid but its primary function is to pprovide frequency q y regulation g and control. In the daytime, a period with a high demand for power, the plant generates electricity. But at night, a period of low demand, demand Kalayaan pumps water from Laguna Lake into Caliraya, an ingenious way of storing energy Hydroelectric Power y Sizes of Hydropower Plants ¾ 1. Large g Hydropower: y p >30 megawatts g ((MW)) ¾ 2. Small Hydropower: 10-30 megawatts (MW) ¾ 3. Mini Hydropower: >100KW-

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