• environmental media scientific knowledge Ch1 Overview

•

Ch1 Overview

• 1.A What Is Environmental Engineering Science?

– Use of Earth’s Resource, Release Contaminants to Environment, Environmental Impact

– Constituents, Impurities, Species, Contaminants, Pollutants

– Instead, the central mission of environmental engineering is to develop and apply scientific knowledge through technology to minimize adverse effects that are associated with

contaminants in environmental media^.

• 何謂環境工程科學？

• 環境工程與其他工程技術之不同處。

• 資源之利用與污染物之控制。

• 污染物控制之發展歷史常涉及人或環境 之傷害。

• 空氣污染、水污染、有害物質污染…

• USEPA 1970 年代成立 …

• 台灣環保署 1987 年成立 …

•

•

Use of Earth’s Resource Release Contaminants to

Environment

Environmental Impact

•

Constituents

Impurities, Species

Contaminants Pollutants

•

The central mission of environmental engineering

Apply scientific knowledge

Technologies

Minimize adverse effects of contaminants

• 環境流體：水、空氣

• 污染物名詞定義： pollutants, contaminants…

• 污染物處理與控制之目標？

• 天然污染與人為污染，理想與現實。

• 環境品質標準與環境排放標準。

• 水體用途標準與放流水標準。

• 空氣品質標準與空氣污染物排放標準。

•

•

• 1.B Domains of Environmental Engineering

– 1.B.l Water Quality Engineering – 1.B.2 Air Qua1ity Engineering

– 1.B.3 Hazardous Waste Management

•

– 1.B.l Water Quality Engineering

• Water treatment, Wastewater treatment

• Water Treatment

– For drinking, for industry, for agriculture

• Water Quality

– Contaminants fate and transport, aquatic ecology, urban runoff ……

– Filtration and chemical disinfection

• Wastewater treatment

– Health problem and poor sanitation

– Physical, chemical and biological treatment – Organic, inorganic and nutrient removal

• 自來水淨水工程與廢水處理工程，水再 生處理之發展。

• 淨水：飲用、工業用、農業用…

• 廢水：環境衛生、預防疾病 (1854 年 , 10,000 死亡 )

• 過濾、消毒 (UV/ 加氯 / 臭氧 )

• 再來水管線、下水道管線、再生水管線

。

• 發展趨勢：微量污染物、環境賀爾蒙、

傳輸宿命、

•

• 飲用水法案、污染物種類眾多…

• 有機化合物、無機化合物、放射性物質

、微生物。

• 點污染源、非點污染源。

•

•_Seletar

•_22,700cmd

•₂₀₀₄

•_Kranji

•_54,600cmd

•_{Jan 2003}

•_Bedok

•_27,300cmd

•_{Jan 2003}

•NEWater pipeline

•NEWater Plant

•Service Reservoir

•_Legend

•_{Ulu Pandan}

•_145,500cmd

•Early- 2007

•新加坡 NEWater 市場規模

•_{現行 4 都市廠產水}

250,000 cmd 主要為工業 用水補充。

12

•₁₂

•₁₂

•美國水再生利用案例 - 南加州西流域

•

•

• 1.B.2 Air Qua1ity Engineering

– Industries and motor vehicles

– Point source, non-point source

– Particulates, sulfur oxides, nitrogen oxides, hydrocarbon, ozone, lead

– Acid deposition, Ozone depletion, Hazardous Air Pollutants, Biomass cookstoves.

• 不完全燃燒之空氣污染。

• 工業排放之空氣污染。

• 光化學煙霧、酸雨、 CFC 臭氧層破 壞、 189 種有害空氣污染物 …

• CO

問題。

•

•

• 1.B.3 Hazardous Waste Management

– Synthetic organic chemicals and natural

– US federal legislation “hazardous”

• Corrosivity, ignitability, reactivity, toxicity

• Specific operations, no precise boundary – Hazardous waste management

• Prevention and remediation

•

• 1.C Context and Concepts

– 1.C.l Concentrations and Other Units of Measure

– 1.C.2 Material Balance – 1.C.3

Factors Governing Contaminant Concentrat

– 1.C.4 Engineering Analysisions

– 1.C.5 Control Opportunities

– 1.C.6 Environmental Regulations – 1.C.7 Precision and Accuracy

– 1.C.8

Magnitudes: Length Scales and Characterist ic Times

•

1.C.1 Concentrations and Other Units of Measure

Concentration

Amounts are commonly quantified either by mass or by moles, where one mole is equal to Avogadro’s number of elements:

Nav=6.02×10²³

.

1 mole of carbon has a mass of 12.0

grams, and 1 mole of carbon dioxide (CO₂

)

has a mass of 12.0+2×16.0=44.0 grams.

• 單位： Dalton, 莫爾 (mole)

• 濃度表示方式：重量濃度、莫爾濃度、

當量濃度。

• 重量比或莫爾比： ppm, ppb

• 水處理領域中 ppm 為重量比。

• 空氣處理領域 ppm 為莫爾筆、體積比

。

• 濃度換算：分子量

•

•

• A special unit is defined for

concentration of charge associated with ions in water. We refer to the ionic

charge concentration associated with some species as its normality (N),

measured in units of equivalents per

liter (eq L

), where one equivalent

represents a net charge equal to one

mole of electrons.

•

 Mass Fraction and Mole Fraction

％ percent 1 part species per 100 part solution

‰ per mil 1 part species per 1000 part solution

ppm part per million 1 part species per 10⁶ part solution

ppb part per billpon 1 part species per 10⁹ part solution

ppt part per trillion 1 part species per 10¹² part solution

•

• Thus, 5 ppb of benzene in air

means that there are 5×10

moles (3×10

molecules) of benzene in a mole of air; on the other hand, 5

ppb of benzene in water means

that 1g of water contains 5×10

g

of benzene.

•

1.C.2 Material Balance 1.C.2 Material Balance

Material balances are applied for both conserved and nonconserved properties of matter. An

example of a conserves property is chemical element.

• Conserved properties are not changed by

transformation processes. Chemical reactions do not change the amount of a chemical element in a system.

• An example of a nonconserved property is a chemical compound, since reactions change the quantities of compounds.

•

1.C.3 Material Balances on Flows

• A wastewater stream containing a

contaminant concentration C

volumetric rate Q_w

into a river. Upstream of the discharge, the contaminant

concentration in the river is C

Assuming complete mixing of the

wastewater stream in the river at the point of discharge, what is the contaminant

concentration immediately downstream?

•

1.C.3 Material Balances on Flows

•

1.C.3 Material Balances on Flows

• SOLUTION ^： Q_mix=Q_r+Q_w

Q_mixC_mix= Q_rC_r + Q_wC_w

• Therefore,

C_mix = (Q_rC_r + Q_wC_w )/ (Q_r+Q_w)

• The concentration of contaminants does not

change in the fluid streams as they diverge, so the composition of each branch is the same as in the entering branch.

•

1.C.3 Factors Governing Contaminant Concentrations

Sources Transformation

processes Transport processes

Removal mechanisms

Concentrations

Adverse effects

•

1.C.4 Engineering Analysis

• Analysis is at the heart of environmental engineering science. We analyze both

engineered and natural environmental systems, usually for one of two major

purposes: to predict how they will behave

• Analyses may be conducted at several

levels, from simple range-finding

•

1.C.4 Engineering Analysis

• Steps ：

1.Translate the physical system into a

2.Solve the mathematical problem to

3.Interpret the significance of the result for the physical system.

•

1.C.5 Control Opportunities

• In the past, the major solution to pollution

• Human activities have reached a scale that is sufficient to cause regional and even

. It is

certainly no longer the case that dilution

suffices to solve environmental quality

problems.

•

1.C.5 Control Opportunities

• The activity that generates the waste is the first link in this chain.

• The next opportunity occurs when waste is present

• The final opportunity occurs after the waste

has been released to the environment.

•

• Applying pollution control measures at the generating process is known as

• Control measures applied after the waste has been generated but before it is

discharged are termed end-of-the-pipe

• Corrective measures applied after the waste has been released are known as

environmental restoration.

1.C.5 Control Opportunities

•

1.C.5 Control Opportunities

• In water quality engineering, environmental control is most frequently applied at two

points:

– to water before it is delivered to the consumer

– to wastewater before it is released to the environment

• Air pollutants control methods focus on the

effluent streams that may lead to airborne

release of pollutants.

•

• Most environmental engineering activities are directly or indirectly motivated by

environmental regulations.

• Pollutant regulations are based on technical information concerning :

– health effects and other environmental costs of pollution.

– technology and cost of control.

1.C.6 Environmental Regulations

1.C.6 Environmental Regulations

•

1.C.6 Environmental Regulations 1.C.6 Environmental Regulations

• The political process is made complex by many factors, two prominent ones being :

– that the technical information is incomplete, uncertain, and sometimes conflicting

– that interest groups seek to influence the decision.

•

1.C.7 Precision and Accuracy

1.C.7 Precision and Accuracy

•

1.C.8 Magnitudes: Length Scales and 1.C.8 Magnitudes: Length Scales and

Characteristic Times

Characteristic Times

•

• Characteristic residence time (

)

• Hydraulic detention time

 

 S/F

• t << 

• t  

• t >> 

• 停留時間、反應時間。

• 重要之設計與操作指標。

• 特徵停留時間、空槽停留時間、空塔停 留時間、水力停留時間、污泥停留時間

。

• 特徵停留時間之意涵：反應狀態、平衡 達成狀態、污染物濃度改變情形。

•

•

• Problem Assignments #1

– 1. Unit conservation exercises and exposure pathway (1.2 in the text)

– 2. A water resource problem (1.8 in the text) – 3. Characteristic times and urban air quality

(1.9 in the text)