summer training report on flexible road pavment

1. A
SUMMER TRAINING REPORT
ON
ROAD DEVELOPMENT AND MAINTENACE IN RURAL AREAS
At
UTTAR PRADESH PUBLIC WORKS DEPARTMENT
CONSTRUCTION DIVISION-4
Submitted for Partial Fulfilment of
DIPLOMA
IN
CIVIL ENGINEERING
SUBMITTED TO: SUBMITTED BY:
DEPARTMENT OF CIVIL ENGINEERING NITIN KANAUJIYA
B N COLLAGE ENGINEERING B.TECH. 3TH
YEAR
LUCKNOW 1234567

2. ACKNOWLEDGEMENT
I, NITIN KANAUJIYA shows my greatest thanks to Executive Engineer Mr. Sunil Kumar and
all the PWD engineers associated with this summer training for his proper guidance, useful
suggestions and timely treatment where ever required during the entire training. My best
wishes to UPPWD for giving me a chance for this summer training and know about flexible
pavement construction. My special thanks goes to Mr. Jwala Prasad Ji J.E. UPPWD
Construction Division 4 and last but not least the workers for a great coordination at site
irrespective of their daily working.
DATE : 28 June 2015 NITIN KANAUJIYA

3. TABLE OF CONTENT
1. ABSTRACT
2. INTRODUCTION
2.1. Objective of This Report
2.2. Background
2.3. Recent Scenario of Roads
2.4. Road Classification
3. LOCATION OF PROJECTAREA
3.1. Project Construction Site
4. LITERATURE
4.1. Map Study
4.2. Reconnaissance
4.3. Preliminary Survey
4.3.1. Traversing
4.3.2. Levelling
4.3.3. Drainage System and Rainfall
4.3.4. Soil Survey
4.3.5. Material Survey
4.3.6. Traffic Survey
4.3.7. Determination of Centre Line
4.3.8. Final Location and Detailed Survey
5. METHODOLGY
5.1. Earthwork
5.1.1. Excavation
5.1.2. Embankment
5.2. Preparation of Sub Grade
5.3. WBM ( Sub base / Base Course )
5.3.1. Materials
5.3.1.1.Coarse Aggregates
5.3.1.2.Stone Screening
5.3.1.3.Proportioning of materials
5.4. Pavement Construction
5.4.1. Preparation of Base
5.4.2. Spreading Coarse Aggregate
5.4.3. Rolling
5.4.4. Application of Screening
5.4.5. Sprinkling of Water and Grouting
5.4.6. Application of Binder Material
5.4.7. Setting and Drying
5.5. Design Criteria
5.5.1. DesignProcedure

4. 5.5.2. DesignTraffic
5.5.3. DesignLife
6. CONCLUSION
7. REFERENCES

5. 1. ABSTRACT
Rural Connectivity becomes a critical component in the socio-economic development of rural people
by providing access to amenities like education, health, marketing etc. It has been established that
investments in rural roads lifts rural people above the poverty line. The evidence also indicates that as
the rural connectivity improves, the rural poverty levels come down. There had been imbalanced
development of the rural road network in country. Some States provided cent per cent connectivity
while some others did not have enough financial resources at their disposal and consequently
connectivity remained at low levels.
Village roads constructed in any places are constructed by two types pavement based on CBR. These
two methods are-
1. Flexible pavement construction
2. Rigid pavement construction
This report deals with the flexible pavement type construction which is used where soil are enough to
sustain loads and did not settle down more or where the soil used is not sandy or clayey. Soil having
CBR good i.e. up to 7 or high this type of pavement is provided, Generally VR is flexible pavement
roads. I have done my training on Flexible pavement type construction. In this type of construction we
use WBM, GSB, MSB etc.

6. 2. INTRODUCTION
Rural development has become a matter of growing urgency for considerations of social justice,
national integration, and economic rising and inclusive growth. For rural development, the provision
of rural road network is a key component to enable the rural people to have access to schools, health
centres and markets. Rural roads serve as an entry point for poverty alleviation since lack of access is
accepted universally as a fundamental factor in continuation of poverty. India launched the era of
planned development in 1951, a few ports and around 400,000 KMS of serviceable road network.
Accessibility to villages was poor as only about 20 percent of them had all weather road links. The
Government laid down a framework for accelerated growth through investments in irrigation, power,
heavy industry and transport. Side by side, stress was laid on provision of social infrastructure
(education and health) and integrated rural development including agriculture. Rural roads act as a
facilitator to promote and sustain agricultural growth, improve basic health, provide access to schools
and economic opportunities and thus holds the key to accelerated poverty reduction, achievements of
MDG , socio-economic transformation, national integration and breaking the isolation of village
communities and holistic and inclusive rural development. A major thrust to the development of rural
roads was accorded at the beginning of the Fifth Five Year Plan in 1974 when it was made a part of
the Minimum Needs Programme. In 1996, this was merged with the BMS programmes. The works of
village tracks were also taken up under several employment creation and poverty alleviation
programmes of the Central and State Governments.
2.1. Objectives of This Report
The objective of this report is to show you what I have learnt through my Industrial Training. What
are the various methods to implement in the road constructions, pavement designing, providing
camber, shoulder, and mixing of bitumen with the aggregates and providing various coats like prime
coat, tack coat and seal coat and various other ways to construct VR.
2.2. Background
In the year 2000, around 40 per cent of the 825,000 villages in India lacked all-weather access roads.
This constrained economic activities and access to essential services. Nearly 74 per cent of India’s
rural population, constituting the majority of India’s poor, were not fully integrated into the national
economy. The rural roads sector, which is a State subject, also lacked adequate planning and
management due to poor coordination between multiple funding streams and agencies. Investing in
rural roads was given low priority and viewed in isolation from the need for State and National
Highways.
TABLE 1.0
While the targets envisaged in terms of length were achieved, there grew imbalanced development of
the rural road network. Some States provided cent per cent connectivity while some others did not
have enough financial resources at their disposal and consequently connectivity remained at low
levels. There were also problems of inadequate funds for maintenance, up gradation and rehabilitation
of existing rural roads. A network approach and provision of sustainable accessibility with assured
maintenance was virtually absent.
The table given below shows the progress of rural roads till launching PMGSY-
Year Accessibility percentage
of village with population
above 1000
Overall village
accessibility
AVG distance of a village
from a Road
1950-1951 32 20 10

7. 1960-1961 36 22 8
1970-1971 40 25 5
1980-1981 46 28 4
1990-1991 73 44 3
2000-2001 90 54 2
2.3. Recent Scenario of Roads
Recently the road development scenario is like this-
Road Development Plan Vision: 2021 formulated by Chief Engineer in-charge of roads under the
aegis of the Indian Roads Congress has served as sound reference framework for the Central and State
Governments to formulate their successive Five Year Plans. As a result, the road network now stands
at 3.3 million KMS. Of this, rural roads comprise around 2.7 million KMS, i.e. about 85 percent.
Overall village accessibility stood at 54 percent in the year 2000, although position in respect of
accessibility to large size habitations has been much better.
2.4. Road Classification
Road classification is primarily based on a variety of criteria, such as, traffic volume, road-width
and surface type and also on links between specific locations. If warranted, the roads are reclassified
to the next higher category keeping in view the traffic density, tourist usage, and industrial
importance.
The roads in the State of Uttar Pradesh are classified into the following five categories based on
functional and administrative criteria:
• National Highways (NH)
• State Highways (SH)
• Major District Roads (MDR)
• Other District Roads (ODR)
• Village Roads (VR)
The Public Works Department (PWD) is the major department dealing with the State Highways ,
Major District Roads, Other District Roads and a part of the Village Roads in the state.
TABLE 2.0 Road length of the Network
ROAD
CATEGORY/DATE
31-3-2002 31-3-2003 31-3-2004 31-3-2005 31-3-2006
National Highway 4860 4931 4931 5583 3825
State Highway 9098 9138 9138 8546 8553
Major District Road 7291 7251 7339 7274 7345
Other District Road 25702 25702 26015 28400 29179
Village Road 67978 71041 71041 77363 78011
Total 114929 118063 118464 127166 126913

8. 3. LOCATION OF PROJECTAREA
Construction work done by UPPWD was going on various sites. These sites are mainly in rural areas
where proper construction of roads are not in sufficient amount means a lot of villages , there is no
proper road in these areas. This is not for only one village actually this is the story of every two
villages. Saying that this is the story of every two village is also not right. Each village has no proper
roads various agencies are working to link up the villages with cities these are NAREGA, NABARD,
MGNAREGA and PWD- construction part etc. In my city construction was going at various places
NIMGAON,MITAULI, PIPRACHEENTH,SARAIYAN,KHURDA,GAURIYA etc at district level.
All places mentioned above, the construction of village roads was FLEXIBLE type PAVEMENT.
These roads were constructed at district level. Various engineers were working on construction of
flexible type pavement. These are some pictures of locations where this work was going on-
3.1. Pictures of Construction Site
NIM GAON SITE

9. GUARIYA SITE
SARAIYAN SITE

10. Construction going on PIPRACHEENTH
4. LITERATURE REVIEW
Before start a highway project, the engineering are to be carried out. The surveys may be completed in
different stages mainly four stages. The first three stages consider all possible alternate alignments
keeping I view the various requirement of highway. The fourth stage is meant for the detailed survey
of selected alignments.
But for a new project various steps are to be followed-
1. Map Study
2. Reconnaissance
3. Preliminary Surveys
4. Final locations and detailed surveys
4.1. Map Study
If the topographic map of the area is available, it is possible to suggest the likely routes of the road. In
India topographical maps are available from Survey of India, with 15 or 30 m contour intervals. The
main features like rivers, hills, valleys etc. are also shown on these maps. By careful study of such
maps, it is possible to have an idea of several possible alternate routes so that further details of these
may be studied later at the site. The probable alignment can be located on the map from details
available on the map.
Thus from the map study alternate routes can be suggested. It may also be possible from map study to
drop a certain route in view of any unavoidable obstruction or undesirable ground, en route. With the
help of the available topographic map of the area and data collected from the satellite.

11. 4.2. Reconnaissance
The second stage of surveys for highway location is the reconnaissance to examine the general
character of the area for deciding the most feasible routes for detailed studies. A field survey party
may inspect a fairly broad stretch of land along the proposed alternative routes of the maps in the
field. Simple instruments like Abney level, tangent clinometers, barometer etc. are used by the
reconnaissance party to collect additional details rapidly. This survey gives a general idea of the
topography and other features, field identification of soil and survey of construction material. When
the road passes through hilly or mountainous terrain, additional data regarding the geological
formation may be observed so as to decide the stable and unstable side of the hill for highway
alignment. Thus Soil type along the routes from field identification tests and observation of geological
features.
From the details collected from reconnaissance, the alignment proposed after study may be altered or
even changed completely. As a result of the reconnaissance a few alternate alignments may be chosen
for further study based on practical considerations observed at the site.
4.3. Preliminary Surveys
The main objectives of preliminary survey are:
To survey the various alternate alignments proposed after the reconnaissance and to collect all the
necessary physical information and details of topography, drainage and soil and to compare the
different proposals in view of the requirements of a good alignment. It is basically carried out to
collect the physical information which is necessary in connection with the proposed highway
alignment.
The procedure of preliminary survey is as following-
4.3.1. Traversing
The first step in the preliminary survey is to establish the primary traverse, following the line
reconnaissance. As these traverses are open traverses no adjustment of errors is possible later, so the
angles should be very accurately measured by THEODOLITE.
4.3.2. Leveling
This is also done side by side to give the centre line profiles and typical cross sections. The leveling
work in the preliminary survey is kept to a minimum just sufficient to obtain the approximate earth
work in the alternate alignments.
To draw the contours of the strip of land to be surveyed, cross section levels should be taken at
suitable intervals, generally 100 to 200 meter in plain terrain.
4.3.3. Drainage System and Rainfall
Drainage system and rainfall data are collected so as to estimate the type, number and approximate
size of cross drainage structures. Also the vertical alignment of highway, particularly the grade line is
decided based on the hydrological and drainage data such as HFL, pond water level, depth of water
table, amount of surface runoff, etc.
4.3.4. Soil Survey

12. Soil survey is an essential part of the preliminary survey as the suitability of the proposed location is
to be finally decided based on the soil survey data.
The soil sample collected during the field work are subjected to identification and classification test in
the laboratory. Soil profile is obtained by drawing the longitudinal section along the proposed road
alignment up to the depth of exploration.
4.3.5. Material Survey
Survey for naturally occurring materials like stone aggregates, soft aggregates, etc. and
identification of suitable quarries should be made. Also availability of manufactured
materials like cement lime, brick, etc. and their locations may be ascertained.
4.3.6. Traffic Survey
Traffic surveys conducted in the region from the basis for deciding the number of traffic lanes and
roadway width, pavement design and economic analysis of highway project. Traffic volume counts of
the classified vehicles are to be carried out on all the existing roads in the region, preferably for 24
hours per day for seven days.
4.3.7. Determination of Centre Line
After completing the preliminary surveys and conducting the comparative studies of alternative
alignment the final centre line of the road is to be decided in the office before the final location
survey. After selecting the final alignment, the grade lines are drawn and the geometric elements of
the elements of the horizontal and vertical alignment of the road are designed.
4.4. Final Location and Detailed Survey
Transfer of the alignment from the drawings to the ground by driving pegs along the centre line of
finally chosen alignment, setting out geometric design elements by location of tangent point, apex
point.
Temporary bench marks are fixed at intervals of about 250 meters and at all drainage and under pass
structures. Levels along the final centre line should be taken at all staked points. Leveling work is of
great importance as the vertical alignment, earth work calculations and drainage details are to be
worked out from the level notes. The cross sections level is taken up to the desired width.
A detailed survey is carried out to enable drawing of the soil profile. The data during detailed survey
should be elaborate and complete for preparing detailed plans, design and estimates of the project.
5. METHEDOLOGY
5.1. Earthwork
The sub grade soil is prepared by bringing is to desired grade and camber and by compacting
adequately. The sub grade may be either in embankment or in excavation. It is necessary to decide
the limits of economical haul and lift. Now we discuss about two terms highlighted above:
5.1.1. Excavation

13. It is the process of cutting or loosening and removing earth including rock from its original position,
transporting and damping it as a fill or spoil bank. Earth excavation work may be divided as
excavation or cutting, grading and compaction. Excavation equipments commonly used in highway
projects or any other simple road constructions are bull dozers, scarpers, power shovels, draglines,
clamshells, and hoes.
5.1.2. Embankment
When it is required to raise the grade line of a highway above the existing ground it becomes
necessary to construct embankments. The grade line may be raised due to any reason- to keep the sub
grade above the high ground water table, to prevent damage due to surface water and capillary water,
to maintain design standard.
The design elements in highway embankments are:
1. HEIGHT,
2. FILL MATERIAL,
3. SETTLEMENT,
4. STABILITY OF FOUNDATIONS, AND
5. STABILITY OF SLOPES.
5.2. Preparation of Sub grade
The optimum moisture content should always be maintained by sprinkling requisite quantity of water
in order to keep the sub-grade in established condition in accordance with the direction of Engineer-
in-Charge. The sub-grade must not be allowed to become dry and break-up for want of cohesion. The
final sectioning should be done to proper camber, gradient and super elevation with the help of
template and strings. The rate of preparation and consolidation of sub-grade includes earth work in
cutting and filling up to 22.5 cm thickness, if necessary, in order to achieve the desired profile. The
dressed surface should be properly consolidated by rolling with power road roller of minimum 80-100
KN capacity.
5.3. WBM ( Sub-Base / Base Course)
This work shall consist of clean, crushed aggregates mechanically interlocked by rolling and bonding
together with screening, binding material where necessary and water laid on a properly prepared sub
grade and finished in accordance with the requirements of these specifications and in close conformity
with the lines, grades, cross-sections and thickness as per approved plans or as directed by Engineer-
in-Charge. It is not desirable to lay Water Bound Macadam on an existing thin black topped surface
without providing adequate drainage facility for water that would get accumulated at the interface of
exiting bituminous surface and WBM.
5.3.1. Materials
5.3.1.1. Coarse Aggregate
Coarse Aggregates shall conform to the grading requirement as set forth in TABLE-3.0
Table-3 COARSE AGGREGATES based on their grading
Size of Scre e nings IS Sie ve De signation % by We ight Passing
IS Sie ve

14. 5.3.1.2. Stone Screening
Screening to fill voids in the coarse aggregates shall generally consist of the same material
as the coarse aggregate. Screening shall conform to the grading requirements as set forth in
Table – 4.
Table – 4 Stone screening based on their percent pass
5.3.1.3. Proportioning of Materials
Approximate quantities of coarse aggregate and stone screenings required for Water Bound
Macadam base / sub-base course shall be as mentioned in Table-5.
Table – 5 (Quantity for 10 sq m Area)
Classific
ation
Size /
Range
Compac
te d
Thickne
ss
Ne t
Quantit
y*
Stone Scre e ning Binding
Mate rialGrading
Classification
& Size
For WBM Sub-
base / Base
Course
(Ne t Quantity)
Grade –
I
45 mm
– 90
mm
100 mm 1.245 m3
Type-A
(13.2 mm)
0.285 m3
0.10 m3
Grade –
II
45 mm
– 63
mm
75 mm 0.935 m3
Type-A
(13.2 mm)
0.135 m3
0.09 m3
* Net quantity means – the quantity of metal measured in stacks and reduced by 7.5%.
13.2 mm 13.2 mm
11.2 mm
5.6 mm
180 micron
100
95-100
15-35
0-10
Size of Aggre gate IS Sie ve Designation % by We ight Passing
IS Sie ve
Grade – I (45 mm to 90 mm)
Grade – II (45 mm to 63 mm)
100 mm
80 mm
63 mm
40 mm
20 mm
80 mm
63 mm
50 mm
40 mm
20 mm
100
65-85
25-60
0-15
0-05
100
90-100
35-70
0-15
0-05

15. 5.4. Pavement ConstructionOperations
5.4.1. Preparation of Base
The surface of the sub grade / sub-base base to receive the Water Bound Macadam course
shall be prepared to the specified lines grades & camber and made free of dust and other
extraneous material. Any soft yielding places shall be corrected in an approved manner and
rolled until firm surface is obtained if necessary by sprinkling water. Any sub
base/base/surface irregularities, where predominant shall be made good by providing
appropriate type of profile corrective course (levelling course).
5.4.2. Spreading Coarse Aggregates
The coarse aggregate shall be spread uniformly and evenly upon the prepared sub -grade to
proper profile by using templates placed across the road about 6m apart in such quantities
such that the thickness of each compact layer is not more than 100mm for Grade -I and 75
mm for Grade-II. Wherever possible, approved mechanical devices such as aggregate
spreader shall be used to spread the aggregates uniformly so as to minimize the need for
manual rectification afterwards.
The surface of the aggregates spread shall be carefully checked with templates and all high
or low spots remedied by removing or adding aggregates as may be required. The surface
shall be checked frequently with a straight-edge while spreading and rolling so as to ensure
a finished surface as per approved drawings.
The course aggregates shall not normally be spread more than 3 days in advance of the
subsequent construction operations.
5.4.3. Rolling
Immediately following the spreading of the coarse aggregates, rolling shall be started with
three wheeled Power Roller of 80-100 KN capacity or Vibratory Rollers of 80-100 KN
static weight. The type of roller to be used shall be approved by the Engineer -in-Charge
based on trial run Rolling shall be discontinued when the aggregates are partially
compacted with sufficient void space in them to permit the application of stone screenings.
The rolled surface shall be checked transversely and longitudinally, with templates and any
irregularities corrected by loosening the surface, adding or removing necessary amount of
aggregates and re-rolling until the entire surface conforms to desired grade and camber. In
no case shall be use of screenings be permitted to make up depressions. Material which gets
crushed excessively during compaction or becomes segregated shall be removed and
replaced with suitable aggregates.
5.4.4. Application of Screenings
After the coarse aggregate has been rolled completely, screenings to completely fill the
interstices shall be applied gradually over the surface. These shall not be damp or wet at the
time of application. Dry rolling shall be done while the screenings are being spread so that
vibrations of the roller cause them to settle into the voids of the coarse aggregates. The

16. screenings shall not be dumped in piles but be spread uniformly in successive thin layers
either by the spreading motions of hand shovels or by mechanical spre aders.
The screenings shall be applied at a slope and uniform rate (in three or more applications)
so as to ensure filling of all voids. This shall be accompanied by dry rolling and broom with
mechanical or hand brooms.
5.4.5. Sprinkling of Water and Grouting
After the screenings have been applied the surface shall be copiously sprinkled with water
swept and rolled. Hand brooms shall be used to sweep the wet screenings into voids and to
distribute them evenly. The sprinkling, sweeping and rolling operations shall be continued,
with additional screenings applied as necessary until the coarse aggregate has been
thoroughly keyed, well bonded and firmly set in its full depth and a grout has been formed
of screenings. Care shall be taken to see that the base or sub-grade does not get damaged
due to the addition of excessive quantity of water during construction.
5.4.6. Application of binder Material
After the application of stone screening in accordance with Clauses 8.034 and 8.035 the
binding material where it is required to be used shall be applied successively in two or
more thin layers at a slow and uniform rate. After each application, the surface shall be
copiously sprinkled with water, the resulting slurry swept in with hand brooms or
mechanical brooms to fill the voids properly and rolled during which water shall be applied
to the wheels of the roller if necessary to wash down the binding material sticking to them.
These operations shall continue until the resulting slurry after filling of voids forms a wave
ahead of the wheels of the moving roller.
5.4.7. Setting and Drying
After the final compaction of Water Bound Macadam course the pavement shall be allowed
to dry overnight. Next morning hungry spots shall be filled with screenings or bending
materials as directed, lightly sprinkled with water if necessary and rolled. No traffic shall
be allowed on the road until the macadam has set.
5.5. DesignCriteria
Design detail of embankment and cut slopes, foundation of embankments and bridges and pavement
layers. Here we dealt with the design of pavements i.e. flexible pavement on which I have done my
training. The pavements have been modelled as a three layer structure and stresses and strains at
critical locations have been computed using the linear elastic model. To give proper consideration to
the aspects of performance, the following three types of pavement distress resulting from repeated
(cyclic) application of loads are considered:
1. Vertical compressive strain at the top of the sub-grade which can cause sub-grade deformation
resulting in permanent deformation at the pavement surface.
2. Horizontal tensile strain or stress at the bottom of the bituminous layer which can cause fracture
of the bituminous layer.
3. Pavement deformation within the bituminous layer.
5.5.1. Design procedure

17. Based on the performance of existing designs and using analytical approach, simple design charts and
a catalogue of pavement designs are added in the code. The pavement designs are given for sub grade
CBR values ranging from 2% to 10% and design traffic ranging from 1 MSA to 150 MSA for an
average annual pavement temperature of 35 C. The later thicknesses obtained from the analysis have
been slightly modified to adapt the designs to stage construction. Using the following simple input
parameters, appropriate designs could be chosen for the given traffic and soil strength: Design traffic
in terms of cumulative number of standard axles; and CBR value of sub grade.
5.5.2. DesignTraffic
The method considers traffic in terms of the cumulative number of standard axles (8160 kg) to be
carried by the pavement during the design life. This requires the following information:
1. Initial traffic in terms of CVPD
2. Traffic growth rate during the design life
3. Design life in number of years
4. Vehicle damage factor (VDF)
5. Distribution of commercial traffic over the carriage way.
Initial traffic is determined in terms of commercial vehicles per day (CVPD). For the structural design
of the pavement only commercial vehicles are considered assuming laden weight of three tonnes or
more and their axle loading will be considered. Estimate of the initial daily average traffic for any
road should normally be based on 7-day 24-hour classified traffic counts (ADT). In case of new roads,
traffic estimates can be made on the basis of potential land use and traffic on existing routes in the
area.
Traffic growth rates can be estimated as:
1. By studying the past trends of traffic growth, and
2. By establishing econometric models. If adequate data is not available, it is recommended that an
average annual growth rate of 7.5 percent may be adopted.
5.5.3. Designlife
For the purpose of the pavement design, the design life is defined in terms of the cumulative number
of standard axles that can be carried before strengthening of the pavement is necessary. It is
recommended that pavements for arterial roads like NH, SH should be designed for a life of 15 years,
EH and urban roads for 20 years and other categories of roads for 10 to 15 years.

18. 6. CONCLUSION
PMGSY is being implemented since the Year 2000. The projects for 109010 habitations have been
sanctioned out of total 136464 eligible habitations by clearing the proposals for 420637 KMS roads.
In order to achieve the targets, Rs. 84,731 Crores were released up to March 2011 against the
sanctioned projects of Rs. 1,18,949 crore.
Rural roads comprise over 85 % of the road network and their being kept in serviceable condition is
crucial to the rural / agricultural growth and affording means of access to millions of rural people to
social facilities viz. medical, education as also to market. Assessment criteria of bid capacity of
contractors may be relaxed so that smaller contractors can also participate in PMGSY works. The
time period of execution of road works in these districts may be enhanced from the existing 18
months to 24 months. Specific clauses may be added in the Standard Bidding document to provide for
insurance coverage to machinery engaged in PMGSY works.
With a view to formulate the 12th Five Year Plan and improve the delivery mechanism for effective
implementation of the programme, the Working Group has been constituted under the Chairmanship
of Secretary, Rural Development with members from different organizations and subject experts. The
Working Group, in turn constituted sub-committees on different aspects of rural roads.

19. 7. REFERENCES
1. IRC: 19-2005 Standard Specification and Code of Practice for Water Bound Macadam
(Third Revision)
2. IRC: 37-2001 Guidelines for the Design of Flexible Pavements (Second Revision)
3. Working Group on Rural Roads In the 12th FIVE YEAR (Government of India,
Planning Commission, Ministry of Rural Development October 2011)
4. Highway Engineering (C.E.G. Justo and S.K. Khanna)
5. www.useit.umeciv.maine.edu/ashcrete.html
6. Technical Assistance for Implementation of Institutional Reforms in the Road
Sector of UP PWD
7. IRC method of design of flexible pavements by NPTEL.