रेजेक्स ( Regular expressions )

युजरने भरलेला फॉर्म आवश्यक ते सर्व रकाने योग्य रितीने भरले आहेत का हे तपासण्याच्या पद्धतीला फॉर्म व्हॅलिडेशन असे म्हणतात. अशा फॉर्ममध्ये
युजरने  भरलेला इमेल योग्य फॉर्मटमध्ये आहे की नाही हे तपासून पाहण्यासाठी रेजेक्स ( RegEx) नावाचे सूत्र वापरण्यात येते. पीएचपीमध्ये या रेजेक्सची माहिती मिळत नाही कारण हे सूत्र पर्ल या लँग्वेजचा उपयोग करून लिहिले जाते. रेजेक्स म्हणजे रेग्युलर एक्स्प्रेशन्स.
 आता पर्ल म्हणजे PERL ( Practical Extraction and Report Language). पर्ल फाईलच्या शेवटी .pl  असे एक्स्टेंशन असते.

(http://www.perl.com)

# Comment

Regular expressions

Metacharacters         char meaning

^                                  beginning of string

$                                  end of string

.                                   any character except newline

*                                   match 0 or more times

+                                  match 1 or more times

?                                  match 0 or 1 times; or: shortest match

|                                   alternative

( )                                 grouping; "storing"

[ ]                                 set of characters

{ }                                 repetition modifier

\                                   quote or special

To present a metacharacter as a data character standing for itself, precede it with \ (e.g. \. matches the full stop character . only).

  Repetition

a*                                zero or more a's

a+                                one or more a's

a?                                zero or one a's (i.e., optional a)

a{m}                            exactly m a's

a{m,}                           at least m a's

a{m,n}                         at least m but at most n a's

repetition?                 same as repetition but the shortest match is taken

 

Read "a's" as "occurrences of strings, each of which matches the pattern a". Read repetition as any of the repetition expressions listed above it. Shortest match means that the shortest string matching the pattern is taken. The default is "greedy matching", which finds the longest match. The repetition? construct was introduced in Perl version 5.

Special notations with \

Single characters \t tab

\n                                 newline

\r                                  return (CR)

\xhh                            character with hex. code hh

 "Zero-width assertions" \b "word" boundary

\B                                not a "word" boundary

Matching \w matches any single character classified as a "word" character (alphanumeric or _)

\W                               matches any non-"word" character

\s                                 matches any whitespace character (space, tab, newline)

\S                                matches any non-whitespace character 

\d                                 matches any digit character, equiv. to [0-9]

\D                                matches any non-digit character

Character sets: specialities inside [...]

Different meanings apply inside a character set ("character class") denoted by [...] so that, instead of the normal rules given here, the following apply:

[characters]   matches any of the characters in the sequence 

[x-y]                 matches any of the characters from x to y (inclusively) in the ASCII code 

[\-]                    matches the hyphen character -

[\n]                   matches the newline; other single character denotations with \ apply normally, too 

[^something] matches any character except those that [something] denotes; that is, immediately after the leading [ the circumflex ^ means "not" applied to all of the rest 

 

Examples     expression matches...

a|b                   either of a and b 

^abc|abc$      the string abc at the beginning or at the end of the string 

 

ab{2,4}c          an a followed by two, three or four b's followed by a c 

ab{2,}c            an a followed by at least two b's followed by a c 

ab*c                an a followed by any number (zero or more) of b's followed by a c 

ab+c               an a followed by one or more b's followed by a c 

ab?c               an a followed by an optional b followed by a c; that is, either abc or ac 

a.c                   an a followed by any single character (not newline) followed by a c 

a\.c                  a.c exactly 

[abc]                any one of a, b and c 

[Aa]bc             either of Abc and abc

[abc]+             any (nonempty) string of a's, b's and c's (such as a, abba, acbabcacaa)

[^abc]+            any (nonempty) string which does not contain any of a, b and c (such as defg)

\d\d                  any two decimal digits, such as 42; same as \d{2}

\w+                  a "word": a nonempty sequence of alphanumeric characters and low lines (underscores), such as foo and 12bar8 and foo_

100\s*mk        the strings 100 and mk optionally separated by any amount of white  space (spaces, tabs, newlines)

abc\b              abc when followed by a word boundary (e.g. in abc! but not in abcd)

perl\B              perl when not followed by a word boundary (e.g. in perlert but not in perl stuff)

इमेल  तपासण्यासाठी खालील रेजेक्स वापरले जाते.

^[A-Z0-9._%+-]+@[A-Z0-9.-]+\.[A-Z]{2,6}$

वरील नियमांवरून आपल्याला या रेजेक्सचा अर्थ काढता येईल. पहिले चिन्ह ^ इमेल स्ट्रिंगची सुरुवात तर  $ इमेल स्ट्रिंगचा शेवट दर्शविते. इमेलच्या स्ट्रिंगमध्ये मुख्य तीन भाग [ ] या कंसांनी दाखविले आहेत व ते + चिन्हांनी एकत्र जोडले आहेत.. दुसर्‍या भागाचे पहिले चिन्ह @ असावे व तिसर्‍या भागाचे पहिले चिन्ह . असावे ( \ हे चिन्ह एस्केप कॅरेक्टर आहे.) असे यावरून कळते. चा पहिला पार्ट A-Z0-9 म्हणजे  अल्फान्युमरिक अक्षरांचा व काही विशिष्ट चिन्हांचा  असावा. मधला भाग अल्फान्युमरिक अक्षरांचा व . किंवा - चिन्हांचा तर शेवटच्या भागातील अक्षरे A-Z0-9 म्हणजे अल्फान्युमरिक असावीत व त्या भागातील एकूण अक्षरे २ ते ६ पर्यंत असावीत 

कोड इग्नायटरमध्ये वेबसाईट लिंकमध्ये लागणारी  index.php फाईल काढून टाकण्यासाठी खालील .htaccess  ही फाईल वेबसाईट फोल्डरमध्ये ठेवावी लागते.
RewriteEngine on
RewriteCond $1 !^(index\.php|[Javascript / CSS / Image root Folder name(s)]|robots\.txt)
RewriteRule ^(.*)$ /index.php/$1 [L]

रेजेक्स नियमांचा उपयोग वरील फाईल मध्ये केला आहे. $1 हे फंक्शन RewriteCond च्या सुरुवातीस व शेवटी आहे पहिल्या ओळीचा अर्थ म्हणजे लिंकमध्ये सुरुवातीस index.php किंवा Javascript / CSS / Image root Folder name(s) नसतील ( सुरुवातीच्या ! चिन्हाचा अर्थ) तर वरील सर्व स्ट्रिंग index.php  ने रिप्लेस करावी.   

Use of Information Technology in Pollution Monitoring and Control

Introduction

Rapid urbanization and industrial growth have led to environmental pollution. In India, due to various reasons, there is no effective control on pollution due to industries and urban population leading to heavy risk to public health and damage to natural resources. Use of information technology in the field of environmental pollution control can help to a great extent in improving this situation. Environmental Engineering Expertise with IT capabilities can achieve this task if industries come forward for such change and environmental pollution control authorities encourage such efforts by giving subsidy to industries.

Waste characterization

Treatment of industrial waste involves physiochemical and biological methods and  their effectiveness depends on the influent characteristics. As there is large variation in flow and characteristics of industrial wastes with time, it is essential to monitor continuous changes in quality and flow. Reliable results can be obtained if extensive statistical techniques are employed to predict the response behavior of various treatment units. Operators and chemists are generally unaware of such methods and they rely on instantaneous values of parameters leading to wrong interpretation and improper corrective action. Simple software routines can be used to calculate statistical parameters of relevance.

Waste Treatment Technology

Due to diversity of pollutant characteristics from various sources, proper monitoring of pollutant concentrations requires well furnished testing equipment, thorough knowledge of analysis procedures and trained personnel. It is also essential to monitor the dynamic nature of receiving bodies like air or water to estimate impact of such pollutants on environment considering dilution and dispersion effects and comparison with permissible limits. This often requires use of advanced mathematics, complex calculations and in depth understanding of mixing phenomenon. As monitoring is done generally by employing temporary manpower through subcontracts to private agencies, such refined analysis is seldom done.

In case of controlling pollution at source through effective treatment, proper design and operation of plants is a must. Design and operation of waste treatment plants in India have remained traditional with use of conventional treatment units and operation by untrained personnel. Due to inadequate design of units, fluctuations in flow and characteristics of wastes the performance of such plants is often far from satisfactory. Design of new treatment technology units or augmentation of existing units in the light of new equipment and process theories can achieve significant improvement in process efficiency and better control. Latest information on novel ideas and case studies is available on number of websites related to academic research and environmental consultancy firms. It is not necessary to have long experience and deep study in the subject. Innovation in approach and development of new suitable technology has become comparative far more easy task due to information technology.    

There are various types of treatment flow sheets adopted for waste treatment. However, primary treatment followed by some form of biological treatment is the most method used in most of the cases. Design of treatment units need to be checked for assumptions made about waste characteristics, flow variations, hydraulic and organic loading rates, chemical dose and aeration requirements and treatment efficiencies. It is observed that many a times, inadequacy of treatment units is the cause of plant failure.

The main performance parameters to be monitored and controlled in primary treatment are floating solids, oil and grease and pH. If the design of screen chamber is of adequate capacity and regular cleaning is done, there is effective removal of floating solids. In case of oil and grease removal, pre-separation of oil by providing separate chamber at mill house greatly enhances the removal efficiency.

Activated sludge process is a complex phenomenon and depend on hydraulic and organic loading, air supply and  sludge recycle. There are number of operating parameters such as waste characteristics at different stages which include flow, DO, BOD, SS and pH values to more complex operating parameters like HRT, SVI, Return sludge ratio, SRT, wasting of sludge, nutrients and micro flora which require understanding of phenomenon, prediction of effect of these parameters on plant performance and fast corrective action.

Anaerobic process though easier than aerobic process needs careful and constant monitoring of pH as souring of digester may upset the process. Rate of organic loading, relationship between alkalinity and volatile acids concentration and its effect on pH, COD reduction and its relation to  biogas recovery are some of the crucial issues which need to be handled by the operator.

Control of such parameters requires skilled and properly trained personnel and input of technical expertise to deal with tricky situations. Most of the plants lack these basic requirements leading to poor plant performance.

Role of Information Technology

Everybody is aware that advances in information technology have opened up new alternatives for better production and quality control. New micro controller based instrument gadgets and servo control operated control units have revolutionized the chemical industry.

It is now possible to compile, store and process large static or dynamic data with the use of computers. Data storage cost has become very low and vast information in multimedia format can be stored on CDs. Internet has provided a gateway to unlimited information available on any topic from the world knowledge pool. Lot of technical information can be downloaded at a fraction of cost. However, majority of environmental consultants in India are unaware of this fact and are still sticking to age old design methods and traditional treatment technology.

Review of Database Management System

A database management system (DBMS) consists of a collection of interrelated data and a collection of programs to access that data. The primary goal of a DBMS is to provide an environment that is both convenient and efficient for the user to retrieve required information in proper format and to store the information securely and in classified form with minimum storage space.

 Though there are various methods and computer programming languages available for developing suitable software, for environmental engineer, visual basic is a simplest language which can easily mastered in short time and is and powerful enough to apply for all necessary tasks in waste treatment automation system. Visual Basic programming language with back end database support of MSAccess, Oracle or SQL can be employed to write customized software programs for following

1. To determine flow and characteristic variations in waste streams at various stages
2. To develop inventory of waste treatment equipment and materials with necessary maintenance schedules.
3. To apply mathematical theories of treatment, dilution and dispersion of pollutants.
4. To describe the relationships between parameter values and their effect on plant performance and treatment efficiency.
5. To provide ready reckoner tips from instrument manuals, guidelines, Do’s and Do’nts, explanations, trouble shooting information.

The program can be designed for single user or multi user facility can be incorporated to provide simultaneous data entry. The user interface can be provided in regional language for uneducated operators to understand the status of plant, problem nature and corrective action to improve the performance. Audio and red light alert  systems can help in attracting attention of the workers if there is failure of some unit or parameter value exceeds permissible level needing immediate action. The reports can be generated with charts and graphs in ready submission format. The entire history data of quality parameters of raw and treated wastes can be stored on CDs for analysis and future reference.

It has been promptly employed in water and waste treatment plants in the west. This being the scenario in advanced countries, India has not yet initialized this process in environmental engineering field.

Chemical industry has already adopted this technology for process control and quality monitoring of raw materials and finished products. Most of the industries have necessary instrumentation for the main plant and extension of such facilities to ETP can be done easily by modernization of the laboratory and treatment units. In fact, it should be made mandatory for new factories and phased implementation for existing effluent treatment plants considering the present unsatisfactory conditions as regards pollution control objectives.

Number of commercial software programs are available for managing inventory, monitoring test parameters and process control in chemical industry, However, in case of Effluent Treatment Plants, there are few imported software programs available which can handle all functions in the ETP and govern the plant performance. Moreover, these programs heavily depend on complete automation and data logging facilities which are not present in most of the effluent treatment plants. It is therefore necessary to develop tailor made customized software to cater the needs of waste treatment plants in India with typical blending of manual and automatic control devices. Enterprise resource planning in pollution control technology can provide better control over performance parameters and environmental technologists should take full advantage of the advances in the field of information technology.

Dnyandeep Infotech Pvt. Ltd. is developing such a comprehensive and flexible hardware-software package with control panel for easy and effective operation of plants. It is proposed that temperature, pH and flow measurements, chemical dose adjustments, operation of valves should be done by providing appropriate microcontroller based instrumentation with data logging and integration facilities. Inventory analysis, maintenance schedules and trouble shooting know how can be embedded in customized software which can accept the automatic data logging as well as manual data entry to suit typical Indian scenario. It can assist in material balance calculations, detection of losses, identify possibilities of waste minimization. Timely reports can be prepared easily. For large industrial units, intranet solutions with multi user operation can be developed.

The key data and reports can be remotely accessed via internet to authorized persons. Interactive website will be linked to such in plant software system such that online training and advice can be obtained from consultants in case of difficulty. Implementation of such a system will help the law enforcement authorities in monitoring the effluent quality and investigating the failure reasons in plant operation.

Way Ahead

 Dnyandeep Infotech Pvt. Ltd. has started work on this project with the help of KIT College of Engineering, Kolhapur and has launched a website www.envis.org to propagate this idea, train the personnel and provide advisory services in automation and system design of Water and Waste water Treatment Plants. Development of Environmental knowledge databases including human resources in Environmental Field available in India is the primary aim of this website. Use of Information Technology for tackling Environmental Engineering problems is a challenging task with lot of potential both as regards pollution control and employment generation. Active support and participation from all environmental workers is expected for the success in this endeavor.

Design of Dual Media Filters to Suit Existing Water Treatment Plants in India

1. INTRODUCTION

Most of the water treatment plants in India are being overloaded in an attempt to cope up with the ever in­creasing water demand. The existing rapid sand filters form a bottleneck for such overloading with the result that part of the water has to be bypassed without filtration, or it finds its way through cracked filter beds, thereby escaping treatment. Poor pre-treatment and non-availability of skilled person­nel for operating the plant make the situation worse, resulting in large and unpredictable changes in treated water quality. A fact-finding survey by NEERI revealed deteriorated condi­tions of water treatment plants in India during 1972 and the conditions have remained practically the same till now. It is felt that conversion of existing rapid sand filters to high rate dual media filters may form the most practical and economical interim mea­sure that could be adopted to improve the conditions.

No doubt, the solution to the prob­lem lies in improvement in pre-treat­ment conditions and augmentation of plant capacities. But it must be ad­mitted that skilled personnel and equipment necessary for proper control of coagulation and availability of finan­cial resources for installation and maintenance of improved pre-treat­ment facilities, or construction of sup­plementary units are beyond the reach of most of the water works in India.

Does it mean that the present state of affairs should continue till these obsta­cles are overcome?

Fortunately, dual media filters have a capacity of functioning even under con­ditions of poor pre-treatment and in­creased flow. Experience in the West as well as in India confirm this. Another advantage in adoption of these filters is that existing filters can be converted to dual media filters with minor changes at a very low cost. The design of such filters is really a difficult task as no established norms can.be adopted due to limitations imposed by existing condi­tions. The present paper tries to evolve a rational approach for design of such converted filters.

Design of dual media filters for new installations has not been considered here as it would be based on entirely different aspects.

2. DESIGN CONSTRAINTS

Design of any filter is based on sus­pension characteristics, filter structure, operating parameters and expected filtrate quality. Considering these, the constraints imposed by prevailing con­ditions in the water treatment plants can be described as follows:

(i) Suspension Characteristics:

Due to uncontrolled alum dose, in­effective flocculation and short circuit­ing in settling tanks, the water ap­plied to the filters has large concentra­tion of turbidity, with significant per­centage of large settleable flocs along­with partially stabilized but unfloccu­- lated colloids. The observations at Kanpur Water Works indicated that the turbidity range is from 15-30 FTU, with about 40 per cent of large floc turbidity which invariably gets strained in the top filter layers.

This can be taken as a representative characteristic of applied water, as in most of the cases the situation is more or less identical. Moreover, along with rise in turbidity levels, there is a change in nature of turbidity also. Thus in rainy season the turbidity levels may shoot upto 100 FTU and during late winter and summer "difficult to floccu­late" algal turbidity may pose prob­lems.

(ii) Filter Structure:

Most of the filtration plants are pro­vided with rate controllers and have submerged inlet flow conditions, thus limiting the standing water depth over the filter: medium. The structure of the filter does not provide any allow­ance for increasing the depth of filter medium, which is restricted to 0.6 to 0.75 m. The limiting head loss avail­able for filtration seldom exceeds 2.0 m, thereby preventing longer filter runs

(iii) Operating Parameters:

The filters are operated by semi­skilled personnel and in some plants, even by coolies; as such, the control of filter operation is very poor. The head loss gauges, rate controllers and dis­charge measuring devices are out of order in most of the cases due to negli­gence. The backwashing is done on a routine time cycle, decided on the con­venience of shift duties. As a result the filter run is terminated only on the basis of time interval without consider­ing limiting head loss, turbidity of filtrate, etc. Any new design of the filter must take into consideration this lacuna in operation, which may not be altered unless skilled personnel are employed. Therefore the filter should be designed to give good filtrate quality and acceptable filtration rate during the entire filter run which should be a pre-determined time interval.

(iv) Expected filtrate quality:

The current design practice in deve­loped countries aims at filtrate turbi­dity to be consistently below 0.2 FTU. However, the filtrate turbidity at such a low level, though desirable, is neither economically feasible under present conditions, nor essential from the point of view of acceptable drinking water standards which permit turbidity up to 5 FTU. Considering the techno-econo­mical feasibility, the filtrate turbidity of 1 FTU may be taken for design.

3. SELECTION OF HIGH RATE FILTER

Of all the high rate filters available, dual, multimedia and mixed media filters can be adopted easily for con­verting old filters. The multimedia filters, though more suitable, may not be practically feasible due to difficulty in the availability and cost of procur­ing and placing different filter media. Mixed media filters advocated by Culp and Culp suffer from the same draw­backs. Dual media filters, though not truly coarse to fine graded, still pro­vide an effective and feasible alterna­tive.

4. DESIGN OF DUAL MEDIA FILTER

Filter Media:

Due to non,.availability of anthracite in India, various other materials like high grade bituminous coal (Param­sh:vam1 et al 1973, Ranade et al'" 1975), crushed coconut shell (Kardile8 1972), berry seeds (Bhole and Nashik­kar1 1974) and kernels of stone fruits like apricots (Ranade and Agrawal 1974) have been tried and were found to be suitable as coarse filter media. Considering the cost, availability and filtration properties, high grade bitu­minous coal seems to be a better choice. However when local conditions favour, use of indigenous filter media may be made as the coarse media. Recent attempts at using plastic granules as filter media may be explored further in. this respect. The lower layer would be of sand for all such filters(ii)

Size Gradation:

High percentage of large flocs in the influent to filter suggests the use of much coarser medium to prevent sur­face mat formation, whereas improper flocculation of some colloids necessiatates greater depth of coarse medium followed by fine medium, with a sharp interface. However, it is reported that use of fine sand produces intermixing. The use of high density fine medium like garnet immediately below the coarse medium may be tried, in order to achieve optimum design. Such com­bination, though it seems to be strange, may give better performance. How­

ever, from availability and cost points of view, use of garnet sand may not be feasible.

Opinions differ regarding the desir­able amount of intermixing at the junction of coarse and fine media. Culp and Culp recommend significant intermixing to achieve ideal "coarse to fine" gradation and claim better filtrate quality and longer filter runs. How­ever there are sufficient reasons to adopt a sharp interface for the filters designed to suit Indian conditions. The turbidity of applied water is of two distinct types and requires two-stage treatment consisting of fine media filterfollowing a coarse media filter. There is less control over the grading of filter media and if the gradation is selected to have significant intermixing there may remain large portion of fine mate­rial which may cause dense packing of intermixing layer, thus defeating the purpose of coarse to fine gradation. This suggests that some degree of in­ termixing is inevitable under present conditions but the design should aim at minimising it.

As regards selection of size grading of filter media, the norm of equal hydraulic settling may be followed as a guide line. But to ensure minimum intermixing, the 10% (wt basis) coarsest grains of top medium and 10% (wt basis) and  finest grains of fine medium (Effective size) should be considered as representative sizes, as they would determine the degree of intermixing. According to Brossman and Malina if the size ratio is in the range of 2 : 1 for coarse and fine media (in case of coal and sand), separation of layers would occur and the same norm can be adhered to in the design. If the densities of coarse and fine media are assumed to be 1.2 and 2.65 respectively as in case of coal and sand, the speci­fications may be stipulated as follows:

Coarse media:

Size range 0.85 to 1.6 mm

E.S. = 1.00 mm U.C. = 1.3 to 1.5

Fine media:

Size range 0.55 to 0.9 mm

E.S. = 0.60 mm U.C. = 1.3 to 1.5

Depth of Media:

Experiments conducted with various combinations of relative depths of indi­vidual media, under high rates of filtra­tion have conclusively proved that coarse media with a depth of 40 to 50 cm can effectively remove large floc turbidity without excessive head loss build-up and can flocculate unflocculat­ed particles. Turbidity reaching the lower sand layers is always less than 5 FTU, even under varying influent turbidity concentrations. The greater depth also prevents clogging of beds when algal suspensions are encounter­ed. Considering the permissible standards for filtrate turbidity, sand layer

of 15 cm thickness is more than enough to ensure filtrate turbidity of less than 1 FTU during the entire filter run.

Use of greater depth of coarse medium also helps in preventing surface mat formation at the interface. It may be argued that a sharp interface would favour such surface straining, but it should be pointed out that the turbidity reaching interface being low, the surface mat formation would take a much longer time as compared to that in a conventional rapid sand filter. The backwash interval for Dual media filters would be much less than for conventional filters, depending on turbidity storage capacity of coarse layer. An increase of head loss due to surface mat formation would not limit the filter run.

normal rates of filtration, becomes a controlling factor at higher rates as the head loss increase with the square of velocity. Fortunately a change in the number of openings on the existing laterals can solve the problem. How­ever, this must be done judiciously after studying the hydraulics of the system, otherwise backwashing may become non-uniform and ineffective after such modifications.

(v) Operation of the Filter :

variable conditions of turbidity and filter components, it is recommended that the filter should be designed to operate with declining rate range of 300 Ipm/sqm to 200 lpm/sqm with 12 hours of filter run. The design is on a much conservative side and would guarantee good filtrate quality. There may be objection to adoption of 12 hours' filter run as the present prac­tice is to have 24 hours filter run. But it should be remembered that the filtration capacity of the converted filter is more than double that of the original filter and a little increase in operation cost is fully justified as the percentage of backwash water require­ment is constant. Moreover this can be adopted without any special train­ing to operators. The backwash pro­cedure would remain unchanged for the converted filters(vi) Performance of the Filter:

Ample data are available on the per­formance of dual media filters, both on pilot scale and field scale, it has been established that these filters can operate at high rates of filtration with consistent high removal efficiency of turbidity and bacteria. Use of such filters in existing water treatment plants would improve filtrate quality and augment the capacity at a rela­tively low cost.

It must be pointed out here that con­version of filter is only an interim mea­sure and improvement in the pre-treat­ment conditions cannot be overlooked.

As the funds become available pre­treatment can be improved by:

1. Proper coagulant dose and effi­cient mixing arrangement.

2. Use of polyelectrolytes to streng­ then the floc.

3. Effective flocculation of all the colloids.

4. Improvement in settling tanks and augmentation of their capa­

cities by use of tube settlers.

5-. Employment of skilled personnel and special training facilities.

Once these changes come into effect the same dual media filters would give excellent filtrate turbidities with longer filter runs of 24 to 36 hours, as the

inlet water would then have turbidity

 of less than 5 F. T.U. and would be of

filterable nature.

(vii) Cost of Conversion :

The cost of the conversion includes the cost of modifications in influent and underdrainage system and cost of plac­ing new media. From the experience gained at Kanpur and Ichhalkaranji Water Works it can be said that this cost is around Rs. 6,000 per mld of plant capacity or Rs. 3,000 per mId of increased capacity If a conversion of a fair sized filtration plant is done the

cost can be further reduced5. CONCLUSION

Dual media filters offer the most appropriate and economical solution -to the present problem of overloaded and inefficient water treatment plants in India. The novelty of these filters 1s that they can be incorporated in the existing system without much change in plant structure or method of opera­tion. The technical know-how for such conversion is fully developed in India.

and the process of conversion of filters can start on a large scale, awaiting only the decision of the concerned authori­ties to solve such -urgent problems.

REFERENCES

1. "Survey of Water Treatment Plants", Technical Digest No.3, CPHERI, Nagpur, (January 1971).

2. Culp G. L. and Culp R. L., "New Con­cepts in Water Purification", Van Nos­trand Reinhold Company, New York, (1974).

3. Conley, W. R., "High Rate Filtration",

      J.A.W.W.A. 64, 3, p. 203, (1972).

4. Ranade S. V., "Engineering and Theoreti­cal Investigations on Dual Media Filters using Indian Bituminous Coals", Ph.D. Thesis, J.I.T., K;anpur, (July 1976).

5. Ranade S. V., Agrawal G. D. and Misra Y. D., "Conversion of Rapid Sand Filter into Dual Media Filter", J. Inst. Public Health Engrs., J., 2, p. 12, (1975).

6. "Manual on Water Supply and Treat­ment", Central Public Health and En­vironmental Engineering Organization, Government of India, (1977).

7. Paramsivan et al., "Bituminous Coal ­A substitute for Anthracite in two Layer Filtration of Water", Indian J. Env. Health, 15, p. 178, (1973).

8. Kardile, J. N. (1972) "Crushed Coconut Shell as a New Filter Media for Dual and Multilayer Filters", J.I.W.W.A. 1, 1, p. 28, (1972).

9. Bhole A. G. and Nashikkar J. T., "Berry Seed Shell as Filter Media", J. Inst. o! Engrs 54, PH 2, p. 45, (1974).

10. Ranade S. V. and Agrawal G. D., "Use of Vegetable Wastes as a Filter Media" presented at the Conference on Engg. Materials and Equipment, The Associa­tion of Engineers, Cal lcutta (1974).

11. Brossman, D. R. and Malina J. F. Jr., "Intermixing of Dual Media Filters and Effects on Performanl;e", Technical Re­port EHE 72-4 CRWR 86, Env. Engg. Lab., University of Texas, Austin, Texas, U.S.A., (1972).

13. Gadgil J. M., "Effect of Media Depths on Performance of Dual Media Filters", M.E. Thesis, Walchand College of Engg., Sangli, (1979).

14. Ranade S. V., Agrawal G. D. and Misra Y. D., "FulJ Scale Trials on Converted Dual Media Filter", J. I.W.W.A., (Octo­ber 1976).