SRJC Course Outlines

3/29/2024 12:09:08 AMWTR 104 Course Outline as of Fall 2012

Changed Course
CATALOG INFORMATION

Discipline and Nbr:  WTR 104Title:  CHEM/LAB DRNK WTR TRTMNT  
Full Title:  Chemistry and Lab Principles for Drinking Water Treatment
Last Reviewed:1/26/2015

UnitsCourse Hours per Week Nbr of WeeksCourse Hours Total
Maximum1.50Lecture Scheduled1.0017.5 max.Lecture Scheduled17.50
Minimum1.50Lab Scheduled1.508 min.Lab Scheduled26.25
 Contact DHR0 Contact DHR0
 Contact Total2.50 Contact Total43.75
 
 Non-contact DHR0 Non-contact DHR Total0

 Total Out of Class Hours:  35.00Total Student Learning Hours: 78.75 

Title 5 Category:  AA Degree Applicable
Grading:  Grade Only
Repeatability:  00 - Two Repeats if Grade was D, F, NC, or NP
Also Listed As: 
Formerly:  ENVT 104

Catalog Description:
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This course is designed for water treatment operators and covers general chemistry and laboratory practices specific to drinking water. The course will provide both a lecture and laboratory component covering topics such as proper sampling procedures, safety in the water treatment plant, unit conversions, dosage and dilution calculations, bacteriological analysis methods, chlorine breakpoint analyses, using and calibrating portable and on-line turbidimeters, and jar testing for evaluating chemical dosages. This class will prepare students for the laboratory procedures portion of the Department of Public Health T2 operator examination.  

Prerequisites/Corequisites:
Course Completion of WTR 102 ( or ENVT 102 or ENVT 200.2)


Recommended Preparation:

Limits on Enrollment:

Schedule of Classes Information
Description: Untitled document
This course is designed for water treatment operators and covers general chemistry and laboratory practices specific to drinking water. Prepares students for the laboratory procedures portion of the Department of Public Health T2 operator examination.  
(Grade Only)

Prerequisites:Course Completion of WTR 102 ( or ENVT 102 or ENVT 200.2)
Recommended:
Limits on Enrollment:
Transfer Credit:
Repeatability:00 - Two Repeats if Grade was D, F, NC, or NP

ARTICULATION, MAJOR, and CERTIFICATION INFORMATION

Associate Degree:Effective:Inactive:
 Area:
 
CSU GE:Transfer Area Effective:Inactive:
 
IGETC:Transfer Area Effective:Inactive:
 
CSU Transfer:Effective:Inactive:
 
UC Transfer:Effective:Inactive:
 
C-ID:

Certificate/Major Applicable: Certificate Applicable Course



COURSE CONTENT

Outcomes and Objectives:
At the conclusion of this course, the student should be able to:
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1. Identify the chemical formulas and calculate the molecular weights of common water treatment chemicals.
2. Perform unit conversions between various types of measurement for concentrations, flows, and pressures.
3. Estimate the dosage of a chemical addition to water during a treatment process.
4. Calculate the new concentration after a dilution has been performed, and estimate the best dilution to achieve a desired outcome.
5. Define and identify normal operating ranges for the following parameters: pH, free and total chlorine turbidity, alkalinity, hardness, and fluoride concentration.
6. Compare bacteriological methods to determine the most appropriate laboratory method to be performed.
7. Compare laboratory analytical data to allowable maximum contaminant limits to decide if the drinking water meets California standards.
8. Estimate the chlorine demand of a water given a chlorine breakpoint titration graph and differentiate between the different areas of the titration curve.
9. Recommend a coagulant dosage based on the turbidity results of a jar test.
10. Determine the best sampling location and recognize necessary laboratory holding times, chain-of-custody procedures and preservation techniques.
11. Measure total and free chlorine residuals in drinking water samples.
12. Calibrate and utilize pH/temperature meters, portable turbidimeters, and on-line turbidimeters.
13. Perform jar testing to propose appropriate coagulant dosages.
14. Perform and interpret bacteriological presence/absence and enumerated bacteriological results for their own use.
15. Classify common water treatment chemicals into acids, bases, oxidizers, etc. using material safety datasheets.
16. Predict chemical incompatibilities based on chemical classifications.
17. Recognize signs of chlorine gas leaks.
18. Define the primary concepts necessary to meet the expected range of knowledge for a T2 operator.  

Topics and Scope
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I. General Chemistry
  A. Lecture
       1. Periodic Table
       2. Elements and molecules
       3. Common Water Treatment Plant Chemical Formulas and Molecular Weights
       4. Writing Chemical Equations
       5. Unit Conversions and Temperature Scales
       6. Acids, Bases, pH
       7. Calculating Chemical Dosages
       8. Performing Dilutions
       9. Chemical Sampling Procedures
       10. Safety in the Laboratory and Water Treatment Plant
  B. Laboratory: Calibrating and performing pH measurements
II. Bacteriological Methods
  A. Lecture
      1. Proper sampling methods and holding times
      2. Dechlorination
      3. Presence/absence test method
      4. Multiple tube fermentation method
      5. Heterotropic Plate Count
      6. Membrane Filtration Method
      7. Presumptive vs. Confirmed Results
  B. Laboratory
      1. Presence/Absence test
      2. Enumerated bacteriological test
III. Chlorine and Fluoride
  A. Lecture
      1. Normal chlorine levels
      2. Chlorine Analysis Techniques (DPD, amperometric)
      3. Chlorine Breakpoint Analysis
      4. Chlorine gas leaks and safety issues
      5. Normal fluoride levels
  B. Laboratory
      1. Chlorine residual analyzer use
      2. Chlorine breakthrough titration example
IV. Turbidity
  A. Lecture
      1. Turbidity Defined
      2. Review Hach NTU manual
      3. Types of equipment, on-line, scatter, portable
      4. Acceptable turbidity ranges for each filtration type
  B. Laboratory
      1. Calibration and use of portable turbidimeter
      2. Calibrate and use of on-line turbidimeter
V. Coagulation/Filtration
  A. Lecture
      1. Calculating Dosages
      2. Concept of Zeta Potential
      3. Determine Optimal Coagulant Dosage
      4. Removing TOC, taste and odor and color
  B. Laboratory: Jar Testing Example
VI. Alkalinity/Hardness
  A. Lecture
      1. Definitions
      2. Impacts on Coagulation
  B. Laboratory
     1. Setting up Calibration Cylinder and Use
     2. Calculating Dosages  

Assignments:
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1. Reading: approximately 10 - 30 pages per week, based on an eight week course.
2. Problem solving homework: 3 assignments (2 on general chemistry, 1 on
dosage calculations.
3. Laboratory skill demonstrations: 3 demonstrations (calibration and use
of turbidimeter, pH analyzer, and chlorine analyzer including determination of an unknown)
4. Weekly quizzes on previous week's material.
5. Final Exam: Laboratory Demonstration  

Methods of Evaluation/Basis of Grade.
Writing: Assessment tools that demonstrate writing skill and/or require students to select, organize and explain ideas in writing.Writing
0 - 0%
None
This is a degree applicable course but assessment tools based on writing are not included because problem solving assessments and skill demonstrations are more appropriate for this course.
Problem solving: Assessment tools, other than exams, that demonstrate competence in computational or non-computational problem solving skills.Problem Solving
25 - 35%
Homework problems
Skill Demonstrations: All skill-based and physical demonstrations used for assessment purposes including skill performance exams.Skill Demonstrations
30 - 40%
Laboratory demonstrations; Final lab demonstration
Exams: All forms of formal testing, other than skill performance exams.Exams
30 - 40%
Multiple choice, True/false, Completion, Problems, Short Answer
Other: Includes any assessment tools that do not logically fit into the above categories.Other Category
0 - 0%
None


Representative Textbooks and Materials:
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Instructor prepared materials  

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